MIC MIC4416BM4

MIC4416/4417
Micrel, Inc.
MIC4416/4417
IttyBitty™ Low-Side MOSFET Driver
General Description
Features
The MIC4416 and MIC4417 IttyBitty™ low-side MOSFET
drivers are designed to switch an N-channel enhancementtype MOSFET from a TTL-compatible control signal in lowside switch applications. The MIC4416 is noninverting and
the MIC4417 is inverting. These drivers feature short delays
and high peak current to produce precise edges and rapid
rise and fall times. Their tiny 4-lead SOT-143 package uses
minimum space.
• +4.5V to +18V operation
• Low steady-state supply current
50µA typical, control input low
370µA typical, control input high
• 1.2A nominal peak output
3.5Ω typical output resistance at 18V supply
7.8Ω typical output resistance at 5V supply
• 25mV maximum output offset from supply or ground
• Operates in low-side switch circuits
• TTL-compatible input withstands –20V
• ESD protection
• Inverting and noninverting versions
The MIC4416/7 is powered from a +4.5V to +18V supply
voltage. The on-state gate drive output voltage is approximately equal to the supply voltage (no internal regulators or
clamps). High supply voltages, such as 10V, are appropriate
for use with standard N-channel MOSFETs. Low supply
voltages, such as 5V, are appropriate for use with logic-level
N-channel MOSFETs.
Applications
•
•
•
•
In a low-side configuration, the driver can control a MOSFET
that switches any voltage up to the rating of the MOSFET.
Battery conservation
Solenoid and motion control
Lamp control
Switch-mode power supplies
The MIC4416 is available in the SOT-143 package and
is rated for –40°C to +85°C ambient temperature range.
Typical Application
Load
Voltage†
* Siliconix
30mΩ, 7A max.
†
Load voltage limited only by
MOSFET drain-to-source rating
MIC4416
0.1µF
3
4
On
Off
Load
+12V
4.7µF
VS
CTL
G
GND
2
1
Si9410DY*
N-channel
MOSFET
Low-Side Power Switch
Micrel, Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel + 1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com
May 2005
1
MIC4416/4417
MIC4416/4417
Micrel, Inc.
Pin Configuration
G
GND
2
1
Part
Identification
Dxx
3
4
VS
CTL
SOT-143 (M4)
Part Number
Standard
Pb-Free
Marking Code*
Standard
Pb-Free
Temperature
Range
Configuration
Package
MIC4416BM4
MIC4416YM4
D10
D10
–40ºC to +85ºC
Non-Inverting
SOT-143
MIC4417BM4
MIC4417YM4
D11
D11
–40ºC to +85ºC
Inverting
SOT-143
*Under bar symbol (_) may not be to scale.
Pin Description
Pin Number
Pin Name
1
GND
2
G
Gate (Output) : Gate connection to external MOSFET.
3
VS
Supply (Input): +4.5V to +18V supply.
4
CTL
Control (Input): TTL-compatible on/off control input.
MIC4416 only: Logic high forces the gate output to the supply voltage.
Logic low forces the gate output to ground.
MIC4417 only: Logic high forces the gate output to ground. Logic low
forces the gate output to the supply voltage.
MIC4416/4417
Pin Function
Ground: Power return.
2
May 2005
MIC4416/4417
Micrel, Inc.
Absolute Maximum Ratings
Operating Ratings
Supply Voltage (VS) .................................................... +20V
Control Voltage (VCTL) .................................. –20V to +20V
Gate Voltage (VG) ....................................................... +20V
Junction Temperature (TJ) ........................................ 150°C
Lead Temperature, Soldering ................... 260°C for 5 sec.
Supply Voltage (VS) ....................................... +4.5 to +18V
Control Voltage (VCTL) .......................................... 0V to VS
Ambient Temperature Range (TA) ............. –40°C to +85°C
Thermal Resistance (θJA)...................................... 220°C/W
(soldered to 0.25in2 copper ground plane)
Electrical Characteristics(Note 3)
Parameter
Condition (Note 1)
Min
Supply Current
4.5V ≤ VS ≤ 18V
VCTL = 0V
VCTL = 5V
Control Input Voltage
4.5V ≤ VS ≤ 18V
VCTL for logic 0 input
VCTL for logic 1 input
Typ
Max
Units
50
370
200
1500
µA
µA
0.8
V
V
10
µA
2.4
Control Input Current
0V ≤ VCTL ≤ VS
Delay Time, VCTL Rising
VS = 5V
CL = 1000pF, Note 2
42
VS = 18V
CL = 1000pF, Note 2
33
VS = 5V
CL = 1000pF, Note 2
42
VS = 18V
CL = 1000pF, Note 2
23
VS = 5V
CL = 1000pF, Note 2
24
VS = 18V
CL = 1000pF, Note 2
14
VS = 5V
CL = 1000pF, Note 2
28
VS = 18V
CL = 1000pF, Note 2
16
Gate Output Offset Voltage
4.5V ≤ VS ≤ 18V
VG = high
VG = low
–25
25
mV
mV
Output Resistance
VS = 5V, IOUT = 10mA
P-channel (source) MOSFET
N-channel (sink) MOSFET
7.6
7.8
Ω
Ω
P-channel (source) MOSFET
N-channel (sink) MOSFET
3.5
3.5
Delay Time, VCTL Falling
Output Rise Time
Output Fall Time
–10
ns
60
ns
ns
40
ns
ns
40
ns
ns
40
ns
VS = 18V, IOUT = 10mA
Gate Output Reverse Current
No latch up
250
10
10
Ω
Ω
mA
General Note: Devices are ESD protected, however handling precautions are recommended.
Note 1:
Typical values at TA = 25°C. Minimum and maximum values indicate performance at –40°C ≥ TA ≥ +85°C. Parts production tested at 25°C.
Note 2:
Refer to “MIC4416 Timing Definitions” and “MIC4417 Timing Definitions” diagrams (see next page).
Note 3:
Specification for packaged product only.
May 2005
3
MIC4416/4417
MIC4416/4417
Micrel, Inc.
Definitions
ISUPPLY
IOUT
MIC4416/7
VSUPPLY
3
MIC4416 = high
MIC4417 = low
4
VS
CTL
G
GND
2
ISUPPLY
VSUPPLY
3
MIC4416 = low
MIC4417 = high
4
VOUT ≈ VSUPPLY
1
Source State
(P-channel on, N-channel off)
IOUT
MIC4416/7
VS
CTL
G
GND
2
VOUT ≈ GND
1
Sink State
(P-channel off, N-channel on)
MIC4416/MIC4417 Operating States
INPUT
5V
90%
2.5V
10%
0V
VS
90%
delay
time
pulse
width
rise
time
delay
time
fall
time
OUTPUT
10%
0V
MIC4416 (Noninverting) Timing Definitions
INPUT
5V
90%
2.5V
10%
0V
VS
90%
delay
time
pulse
width
rise
time
delay
time
fall
time
OUTPUT
10%
0V
MIC4417 (Inverting) Timing Definitions
Test Circuit
VSUPPLY
MIC4416/7
3
4
VS
CTL
G
GND
2
1
CL
VOUT
5V
0V
MIC4416/4417
4
May 2005
MIC4416/4417
Micrel, Inc.
Typical Characteristics Note 3
Quiescent Supply Current
vs. Supply Voltage
300
200
100
VCTL = 0V
0
3
6
9
12 15
SUPPLY VOLTAGE (V)
100kHz
10
10kHz
1
VSUPPLY = 5V
0.1
18
1
10kHz
1
VSUPPLY = 18V
100
Output Rise and Fall Time
vs. Load Capacitance
Supply Current
vs. Frequency
100
SUPPLY CURRENT (mA)
10
CAPACITANCE (nF)
10
0.1
100
VSUPPLY = 18V
10
10
TIME (µs)
5V
10
CAPACITANCE (nF)
100
Output Rise and Fall Time
vs. Load Capacitance
VSUPPLY = 18V
fCTL = 50kHz
FALL
10
1
1
VSUPPLY = 5V
fCTL = 50kHz
1
RISE
TIME (µs)
0
1MHz
100kHz
1MHz
SUPPLY CURRENT (mA)
400
Supply Current
vs. Load Capacitance
100
100
VCTL = 5V
SUPPLY CURRENT (mA)
SUPPLY CURRENT (µA)
500
Supply Current
vs. Load Capacitance
1
FALL
RISE
0.1
2000
1000
100
0.1
10
0.1
0.01
FREQUENCY (kHz)
Delay Time
vs. Supply Voltage
60
60
1
10
CAPACITANCE (nF)
100
0.01
Delay Time
vs. Temperature
60
1
10
CAPACITANCE (nF)
100
Delay Time
vs. Temperature
VCTL FALL
50
VCTL RISE
30
20
50
VCTL RISE
40
TIME (ns)
40
TIME (ns)
TIME (ns)
50
30
20
40
30
20
VCTL FALL
VCTL FALL
10
0
10
0
3
6
9
12 15
SUPPLY VOLTAGE (V)
10
VSUPPLY = 18V
0
-60 -30 0 30 60 90 120 150
TEMPERATURE (°C)
VSUPPLY = 5V
0
-60 -30 0 30 60 90 120 150
TEMPERATURE (°C)
18
Rise and Fall Time
vs. Supply Voltage
50
50
Rise and Fall Time
vs. Temperature
50
fCTL = 1MHz
30
FALL
10
RISE
0
May 2005
0
3
6
9
12 15
SUPPLY VOLTAGE (V)
30
40
FALL
RISE
20
VSUPPLY = 5V
fCTL = 1MHz
10
18
0
-60 -30 0 30 60 90 120 150
TEMPERATURE (°C)
5
TIME (ns)
40
TIME (ns)
TIME (ns)
40
20
VCTL RISE
Rise and Fall Time
vs. Temperature
VSUPPLY = 18V
fCTL = 1MHz
30
20
10
FALL
RISE
0
-60 -30 0 30 60 90 120 150
TEMPERATURE (°C)
MIC4416/4417
MIC4416/4417
Output Voltage Drop vs.
Output Source Current
1200
600
400
18V
200
400
0
ON RESISTANCE (Ω)
4
IOUT = 10mA
2
3
6
9
12 15
SUPPLY VOLTAGE (V)
VSUPPLY = 5V
IOUT ≈ 3mA
10
8
6
4
VSUPPLY = 18V
IOUT ≈ 3mA
2
0
-60 -30 0 30 60 90 120 150
TEMPERATURE (°C)
CL = 10,000pF
5,000pF
2,000pF
1,000pF
1
0pF
0.1
1x102 1x103 1x104 1x105 1x106 1x107
FREQUENCY (Hz)
MIC4416/4417
0
3
6
9
12 15
SUPPLY VOLTAGE (V)
4
VSUPPLY = 18V
IOUT ≈ 3mA
Sink
NOTE 7
0
3
6
9
12 15
SUPPLY VOLTAGE (V)
18
Note 3:
Typical Characteristics at
TA = 25°C, VS = 5V,
CL = 1000pF unless noted.
Note 4:
Source-to-drain voltage drop across the
internal P-channel MOSFET =
VS – VG.
Note 5:
Drain-to-source voltage drop across the
internal N-channel MOSFET = VG – VGND.
(Voltage applied to G.)
Note 6:
1µs pulse test, 50% duty cycle. OUT
connected to GND. OUT sources current.
(MIC4416, VCTL = 5V;
MIC4417, VCTL = 0V)
Note 7:
1µs pulse test, 50% duty cycle. VS
connected to OUT. OUT sinks current.
(MIC4416, VCTL = 0V;
MIC4417, VCTL = 5V)
2,000pF
0pF
6
1.0
0
5,000pF
0.1
1x102 1x103 1x104 1x105 1x106 1x107
FREQUENCY (Hz)
Source
NOTE 6
1.5
0.5
VSUPPLY = 18V
1,000pF
Peak Output Current
vs. Supply Voltage
2.0
6
1
200
2.5
8
10
5V
0
-60 -30 0 30 60 90 120 150
TEMPERATURE (°C)
VSUPPLY = 5V
IOUT ≈ 3mA
CL = 10,000pF
18
VSUPPLY = 18V
400
18
Supply Current
vs. Frequency
3
6
9
12 15
SUPPLY VOLTAGE (V)
Control Input Hysteresis
vs. Temperature
600
Output Sink Resistance
vs. Temperature
2
0
800
IOUT = 10mA
100
SUPPLY CURRENT (mA)
SUPPLY CURRENT (mA)
VSUPPLY = 5V
10
Output
Sink Resistance
2
10
200
0
4
12
300
20
40
60
80
100
OUTPUT CURRENT (mA)
0
-60 -30 0 30 60 90 120 150
TEMPERATURE (°C)
Supply Current
vs. Frequency
100
0
6
14
400
100
8
0
18
Output Source Resistance
vs. Temperature
12
18V
200
ON-RESISTANCE (Ω)
ON RESISTANCE (Ω)
ON-RESISTANCE (Ω)
600
10
6
14
VSUPPLY = 5V
20
40
60
80
100
OUTPUT CURRENT (mA)
8
0
500
800
Output
Source Resistance
10
0
1000
HYSTERESIS (mV)
VSUPPLY = 5V
0
600
HYSTERESIS (mV)
VOLTAGE DROP (mV)
800
0
Control Input Hysteresis
vs. Supply Voltage
NOTE 5
NOTE 4
1000
Output Voltage Drop vs.
Output Sink Current
CURRENT (A)
1200
VOLTAGE DROP (mV)
Micrel, Inc.
May 2005
MIC4416/4417
Micrel, Inc.
Functional Diagram
VSUPPLY
VSWITCHED
VS
D1
MIC4417
INVERTING
CTL
Logic-Level
Input
Q2
D4
Load
0.6mA
0.3mA
Q3
R1
2k
G
Q1
D2
D3
35V
D5
MIC4416
NONINVERTING
Q4
GND
Functional Diagram with External Components
Functional Description
Refer to the functional diagram.
Q2 turns off after the first inverter output goes high. This
reduces the current through Q1 to 0.3mA. The lower current
reduces the drain-to-source voltage drop across Q1. A
slightly lower control voltage will pull the input of the first
inverter up to its threshold.
The MIC4416 is a noninverting driver. A logic high on the CTL
(control) input produces gate drive output. The MIC4417 is
an inverting driver. A logic low on the CTL (control) input
produces gate drive output. The G (gate) output is used to
turn on an external N-channel MOSFET.
Drivers
Supply
The second (optional) inverter permits the driver to be manufactured in inverting and noninverting versions.
The last inverter functions as a driver for the output MOSFETs
Q3 and Q4.
VS (supply) is rated for +4.5V to +18V. External capacitors
are recommended to decouple noise.
Control
CTL (control) is a TTL-compatible input. CTL must be forced
high or low by an external signal. A floating input will cause
unpredictable operation.
Gate Output
G (gate) is designed to drive a capacitive load. VG (gate
output voltage) is either approximately the supply voltage or
approximately ground, depending on the logic state applied
to CTL.
A high input turns on Q1, which sinks the output of the 0.3mA
and the 0.6mA current source, forcing the input of the first
inverter low.
If CTL is high, and VS (supply) drops to zero, the gate output
will be floating (unpredictable).
Hysteresis
ESD Protection
The control threshold voltage, when CTL is rising, is slightly
higher than the control threshold voltage when CTL is falling.
D1 protects VS from negative ESD voltages. D2 and D3
clamp positive and negative ESD voltages applied to CTL.
R1 isolates the gate of Q1 from sudden changes on the CTL
input. D4 and D5 prevent Q1’s gate voltage from exceeding
the supply voltage or going below ground.
When CTL is low, Q2 is on, which applies the additional
0.6mA current source to Q1. Forcing CTL high turns on Q1
which must sink 0.9mA from the two current sources. The
higher current through Q1 causes a larger drain-to-source
voltage drop across Q1. A slightly higher control voltage is
required to pull the input of the first inverter down to its
threshold.
May 2005
7
MIC4416/4417
MIC4416/4417
Micrel, Inc.
+15V
Application Information
* Gate enhancement voltage
The MIC4416/7 is designed to provide high peak current for
charging and discharging capacitive loads. The 1.2A peak
value is a nominal value determined under specific conditions. This nominal value is used to compare its relative size
to other low-side MOSFET drivers. The MIC4416/7 is not
designed to directly switch 1.2A continuous loads.
MIC4416
0.1µF
3
4
Logic
Input
Supply Bypass
VS
CTL
Standard
MOSFET
IRFZ24†
2
G
1
GND
VGS*
† International Rectifier
100mΩ, 60V MOSFET
Capacitors from VS to GND are recommended to control
switching and supply transients. Load current and supply
lead length are some of the factors that affect capacitor
size requirements.
Figure 1. Using a Standard MOSFET
Logic-Level MOSFET
A 4.7µF or 10µF tantalum capacitor is suitable for many
applications. Low-ESR (equivalent series resistance) metalized film capacitors may also be suitable. An additional 0.1µF
ceramic capacitor is suggested in parallel with the larger
capacitor to control high-frequency transients.
Logic-level N-channel power MOSFETs are fully enhanced
with a gate-to-source voltage of approximately 5V and have
an absolute maximum gate-to-source voltage of ±10V. They
are less common and generally more expensive.
The MIC4416/7 can drive a logic-level MOSFET if the supply
voltage, including transients, does not exceed the maximum
MOSFET gate-to-source rating (10V).
The low ESR (equivalent series resistance) of tantalum
capacitors makes them especially effective, but also makes
them susceptible to uncontrolled inrush current from low
impedance voltage sources (such as NiCd batteries or automatic test equipment). Avoid instantaneously applying voltage, capable of very high peak current, directly to or near
tantalum capacitors without additional current limiting. Normal power supply turn-on (slow rise time) or printed circuit
trace resistance is usually adequate for normal product
usage.
+5V
* Gate enhancement voltage
(must not exceed 10V)
Load
+4.5V to 10V*
4.7µF
MIC4416
0.1µF
3
4
Logic
Input
Circuit Layout
Avoid long power supply and ground traces. They exhibit
inductance that can cause voltage transients (inductive kick).
Even with resistive loads, inductive transients can sometimes
exceed the ratings of the MOSFET and the driver.
VS
CTL
Logic-Level
MOSFET
IRLZ44†
2
G
1
GND
Try a
3Ω, 10W
or
100Ω, 1/4W
resistor
VGS*
† International Rectifier
28mΩ, 60V MOSFET
Figure 2. Using a Logic-Level MOSFET
When a load is switched off, supply lead inductance forces
current to continue flowing—resulting in a positive voltage
spike. Inductance in the ground (return) lead to the supply
has similar effects, except the voltage spike is negative.
At low voltages, the MIC4416/7’s internal P- and N-channel
MOSFET’s on-resistance will increase and slow the output
rise time. Refer to “Typical Characteristics” graphs.
Inductive Loads
Switching transitions momentarily draw current from VS to
GND. This combines with supply lead inductance to create
voltage transients at turn on and turnoff.
VSWITCHED
VSUPPLY
Transients can also result in slower apparent rise or fall times
when driver’s ground shifts with respect to the control input.
Schottky
Diode
4.7µF
Minimize the length of supply and ground traces or use
ground and power planes when possible. Bypass capacitors
should be placed as close as practical to the driver.
MOSFET Selection
MIC4416
0.1µF
3
4
On
Off
Standard MOSFET
VS
CTL
G
GND
2
1
Figure 3. Switching an Inductive Load
A standard N-channel power MOSFET is fully enhanced with
a gate-to-source voltage of approximately 10V and has an
absolute maximum gate-to-source voltage of ±20V.
Switching off an inductive load in a low-side application forces
the MOSFET drain higher than the supply voltage (as the
inductor resists changes to current). To prevent exceeding
the MOSFET’s drain-to-gate and drain-to-source ratings, a
Schottky diode should be connected across the inductive
load.
The MIC4416/7’s on-state output is approximately equal to
the supply voltage. The lowest usable voltage depends upon
the behavior of the MOSFET.
MIC4416/4417
Try a
15Ω, 15W
or
1k, 1/4W
resistor
Load
+8V to +18V
4.7µF
8
May 2005
MIC4416/4417
Micrel, Inc.
Power Dissipation
High-Frequency Operation
The maximum power dissipation must not be exceeded to
prevent die meltdown or deterioration.
Although the MIC4416/7 driver will operate at frequencies
greater than 1MHz, the MOSFET’s capacitance and the load
will affect the output waveform (at the MOSFET’s drain).
Power dissipation in on/off switch applications is negligible.
For example, an MIC4416/IRL3103 test circuit using a 47Ω
5W load resistor will produce an output waveform that closely
matches the input signal shape up to about 500kHz. The
same test circuit with a 1kΩ load resistor operates only up to
about 25kHz before the MOSFET source waveform shows
significant change.
Fast repetitive switching applications, such as SMPS (switchmode power supplies), cause a significant increase in power
dissipation with frequency. Power is dissipated each time
current passes through the internal output MOSFETs when
charging or discharging the external MOSFET. Power is also
dissipated during each transition when some current momentarily passes from VS to GND through both internal MOSFETs.
Power dissipation is the product of supply voltage and supply
current:
4.7µF
MIC4416
0.1µF
3
PD = power dissipation (W)
Logic
Input
VS = supply voltage (V)
IS = supply current (A) [see paragraph below]
4
VS
CTL
D
G
GND
2
1
G
S
Logic-Level
MOSFET
IRL3103*
* International Rectifier
14mΩ, 30V MOSFET,
logic-level, VGS = ±20V max.
Supply current is a function of supply voltage, switching
frequency, and load capacitance. Determine this value from
the “Typical Characteristics: Supply Current vs. Frequency”
graph or measure it in the actual application.
Figure 5. MOSFET Capacitance Effects at High
Switching Frequency
When the MOSFET is driven off, the slower rise occurs
because the MOSFET’s output capacitance recharges through
the load resistance (RC circuit). A lower load resistance
allows the output to rise faster. For the fastest driver operation, choose the smallest power MOSFET that will safely
handle the desired voltage, current, and safety margin. The
smallest MOSFETs generally have the lowest capacitance.
Do not allow PD to exceed PD (max), below.
TJ (junction temperature) is the sum of TA (ambient temperature) and the temperature rise across the thermal resistance
of the package. In another form:
PD ≤
Compare
47kΩ, 5W
to
1kΩ, 1/4W
loads
+4.5V to 18V
1)
PD = VS × IS
where:
2)
+5V
Slower rise time
observed at
MOSFET’s drain
150 − TA
220
where:
PD (max) = maximum power dissipation (W)
150 = absolute maximum junction temperature (°C)
TA = ambient temperature (°C) [68°F = 20°C]
220 = package thermal resistance (°C/W)
Maximum power dissipation at 20°C with the driver soldered
to a 0.25in2 ground plane is approximately 600mW.
G
PCB heat sink/
ground plane
GND
VS
CTL
PCB traces
Figure 4. Heat-Sink Plane
The SOT-143 package θJA (junction-to-ambient thermal resistance) can be improved by using a heat sink larger than the
specified 0.25in2 ground plane. Significant heat transfer
occurs through the large (GND) lead. This lead is an
extension of the paddle to which the die is attached.
May 2005
9
MIC4416/4417
MIC4416/4417
Micrel, Inc.
Package Information
0.950 (0.0374) TYP
1.40 (0.055) 2.50 (0.098)
1.20 (0.047) 2.10 (0.083)
CL
CL
DIMENSIONS:
MM (INCH)
1.12 (0.044)
0.81 (0.032)
3.05 (0.120)
2.67 (0.105)
0.800 (0.031) TYP
0.400 (0.016) TYP 3 PLACES
0.150 (0.0059)
0.089 (0.0035)
8°
0°
0.10 (0.004)
0.013 (0.0005)
0.41 (0.016)
0.13 (0.005)
4-Pin SOT-143 (M4)
MICREL INC. 2180 FORTUNE DRIVE SAN JOSE, CA 95131 USA
TEL
+ 1 (408) 944-0800
FAX
+ 1 (408) 474-1000
WEB
http://www.micrel.com
This information furnished by Micrel in this data sheet is believed to be accurate and reliable. However no responsibility is assumed by Micrel for its use.
Micrel reserves the right to change circuitry and specifications at any time without notification to the customer.
Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product can
reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical implant into
the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A Purchaser’s
use or sale of Micrel Products for use in life support appliances, devices or systems is a Purchaser’s own risk and Purchaser agrees to fully indemnify
Micrel for any damages resulting from such use or sale.
© 2001 Micrel Incorporated
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May 2005