ETC PWR-82330-800W

PWR-82330
SMART POWER 3-PHASE MOTOR DRIVE
FEATURES
DESCRIPTION
APPLICATIONS
The PWR-82330 is a smart Power 3phase Motor Drive Hybrid. The PWR82330 uses a MOSFET output stage
with a 100 Vdc rating, and can deliver
5 A continuous, 10 A peak current to
the load.
Packaged in a small case, these
hybrids are an excellent choice for high
performance, high-reliability motor drives for Military and Aerospace servoamps and speed controls.
This new Smart Power Motor Drive has
CMOS Schmitt trigger inputs for high
noise immunity. High and low-side
input logic signals are XOR’d in each
phase to prevent simultaneous turn on
of in-line transistors, thus eliminating a
shoot through condition.
Among the many applications are
robotics; electro-mechanical valve
assemblies; actuator systems; antenna
and radar positioning; fan and blower
motors for environmental conditioning;
position control of mini-subs, drones,
and RPV’s; and compressor motors for
cryogenic coolers.
The internal logic controls the high and
low-side gate drivers for each phase
and can operate from +5 to +15 V logic
levels. The internal charge pump circuitry provides the required voltage to
high-side gate drives. This provides
constant output performance for
switching frequencies from dc to 50
kHz.
The PWR-82330 hybrid is ideal for
harsh military environments where
shock, vibration, and temperature
extremes are evident, such as missile
applications including fin actuators and
I.R. seeker head movement. The PWR82330 operates over the -55°C to
+125°C temperature range and is available with military processing.
• Small size (2.6" x 1.4" x 0.25")
• 100 Vdc Rating
• 5 A Continuous, 10 A peak
Capability
• High-Efficiency MOSFET Drive
Stage
• Direct Drive from Commutation
Logic
• Six Step Trapezoidal or
Sinusoidal Drive
• Four Quadrant Operation
• Military Processing Available
+CAP
48
50
-CAP
CHARGE PUMP
V+
4
GND
5,18,19
6
8
10
VCC A
VLPI
VUA
VO A
DRIVE
A
VLA
VSS A
14
16
VUB
VLB
DIGITAL
CONTROL
AND
PROTECTION
CIRCUITRY
VCC B
VO B
23
VCC C
VUC
VLC
VO C
DRIVE
C
12
VSS C
VSd
FIGURE 1. PWR-82330 BLOCK DIAGRAM
©
1992, 1999 Data Device Corporation
43,44,45
40,41,42
39
36,37,38
DRIVE
B
VSS B
21
46
33,34,35
32
29,30,31
26,27,28
NOTES
2
TABLE 1. PWR-82330 ABSOLUTE MAXIMUM RATINGS
(Tc = +25°C Unless Otherwise Specified)
PARAMETER
SYMBOL
VALUE
UNITS
SUPPLY VOLTAGE
VCC
100
V
INPUT VOLTAGE
V+
18
V
LOGIC POWER-IN VOLTAGE
VLPI
18
V
VU, VL, VSd
VLPI + 0.5
V
OUTPUT CURRENT
CONTINUOUS
PEAK
lO
IP
5
10
A
A
OPERATING FREQUENCY
fO
50
kHz
CASE OPERATING TEMPERATURE
TC
-55 to +125
°C
CASE STORAGE TEMPERATURE RANGE
TCS
-55 to +150
°C
INPUT LOGIC VOLTAGE
PARAMETER
OUTPUT
Output Current Continuous
Supply Voltage
Output On-Resistance (each FET)
Instant Forward Voltage (intrinsic diode)
Reverse Recovery Time (intrinsic diode)
Reverse Leakage Current
INPUT POWER
Input Voltage (TC=-55°C to +125°C)
Logic Power-in Voltage
V+ Current
Logic Power Input Current
INPUT SIGNALS (See Figure 3)
Positive Trigger Threshold Voltage
Negative Trigger Threshold Voltage
Hysteresis Voltage
Positive Trigger Threshold Voltage
Negative Trigger Threshold Voltage
Hysteresis Voltage
TABLE 2. PWR-82330 SPECIFICATIONS
(TC=+25°C Unless Otherwise Specified)
SYMBOL
TEST CONDITIONS
IO
VCC
RON
VF
trr
Ir
V+ = 15V
VLPI = 15 V
VP
VN
VH
VP
VN
VH
Pin Connections
VLPI = 15 V
VLPI = 15 V
VLPI = 15 V
VLPI = 5 V
VLPI = 5 V
VLPI = 5 V
td(on)
td(off)
tsd
tr
tf
Lower Drive:
Turn-on Propagation Delay
Turn-off Propagation Delay
Shut-down Propagation Delay (see FIGURE 5)
Turn-on Rise Time
Turn-off Fall Time
td(on)
td(off)
tsd
tr
tf
SWITCHING CHARACTERISTICS
( see FIGURE 2)
Upper Drive:
Turn-on Propagation Delay
Turn-off Propagation Delay
Shut-down Propagation Delay (see FIGURE 5)
Turn-on Rise Time
Turn-off Fall Time
td(on)
td(off)
tsd
tr
tf
160
12
5
Test 1 Conditions
VLPI = 15 V
V+ = 15 V
VCC = +28 V
Ip = 10 A
Test 2 Conditions
VLPI = 5 V
V+ = 15 V
VCC = +28 V
Ip = 10 A
3
TYP
28
see note 1
Ip=5A (see note 2)
Ip=5A (see note 2)
Id=1A, did/dt=160A/µs
see note 3
V+
VLPI
I+
ILPI
SWITCHING CHARACTERISTICS
( see FIGURE 2)
Upper Drive:
Turn-on Propagation Delay
Turn-off Propagation Delay
Shut-down Propagation Delay (see FIGURE 5)
Turn-on Rise Time
Turn-off Fall Time
MIN
2.1
1.6
0.9
0.3
15
MAX
UNIT
5
100
0.13
1.25
500
250
A
V
Ω
V
nsec
µA
18
18
150
5
V
V
mA
mA
12.9
3.6
V
V
V
V
V
V
825
1100
1000
125
200
nsec
nsec
nsec
nsec
nsec
825
1100
1000
200
200
nsec
nsec
nsec
nsec
nsec
1150
1400
1050
125
225
nsec
nsec
nsec
nsec
nsec
10.8
4.3
TABLE 2. PWR-82330 SPECIFICATIONS (continued)
(TC= +25°C Unless Otherwise Specified)
PARAMETER
SYMBOL
SWITCHING CHARACTERISTICS (continued)
Lower Drive:
Turn-on Propagation Delay
Turn-off Propagation Delay
Shut-down Propagation Delay (see FIGURE 5.)
Turn-on Rise Time
Turn-off Fall Time
td(on)
td(off)
tsd
tr
tf
TEST CONDITIONS
MIN
TYP
Test 2 Conditions
VLPI = 5 V
V+ = 15 V
VCC = +28 V
Ip = 10 A
MAX
UNITS
1150
1400
1050
125
225
nsec
nsec
nsec
nsec
nsec
tdt
400
nsec
MINIMUM PULSE WIDTH
tpw
150
nsec
THERMAL
Maximum thermal Resistance
Junction Temperature Range
Case Operating Temperature
Case Storage Temperature
θjc
Tj
TCO
TCS
DEAD TIME
each transistor
-55
-55
-55
WEIGHT
7.5
150
125
150
°C/W
°C
°C
°C
1.37
(39)
0z
(g)
NOTES:
1. For Hi-Rel applications, derating per MIL-S-19500 should be observed. (Derate VCC by 70%.)
2. Pulse Width ≤ 300 µs, duty cycle ≤ 2%
3. VCC = 70 V, VU, VL, = logic ‘0’
INTRODUCTION
logic controls the high and low-side gate drivers. Operation from
5 to 15 V logic levels can be programmed by applying the appropriate voltage to pin 6 (VLPI). The PWR-82330 has a ground referenced low-side gate drive. An internal charge pump circuit
supplies the required drive voltage to each of the three high-side
transistors. This provides a continuous high-side gate drive even
during a motor stall. The high and low-side gate drivers control
the N-channel MOSFET output stage. The MOSFETs used in
the PWR-82330 allow output switching up to 50 kHz. The PWR82330 does not have an internal short-circuit or overcurrent protection, which if required, must be added externally to the hybrid.
The 3-phase PWR-82330 is a 5 A motor drive hybrid which incorporates a 100 Vdc MOSFET output stage for high-speed and highefficiency operation. This motor drive is ideal for use in high-performance motion control systems, servo amplifiers, and motor speed
control designs. Furthermore, Multi-axis systems requiring multiple
drive stages can benefit from the small size of this power drive.
The PWR-82330 can be driven directly from commutation logic,
DSP, or a custom ASIC that supplies digital signals to control the
upper and lower transistors of each phase. This highly integrated drive stage has schmitt trigger digital inputs that control the
high and low side of each phase. Digital protection of each
phase eliminates an in-line firing condition, by preventing simultaneous turn-on of both the upper and lower transistors. The
DIGITALLY CONTROLLED INPUTS
The PWR-82330 uses the Schmitt triggered digital inputs (with
hysteresis) to ensure high noise immunity. The trigger switches
at different points for positive and negative going signals.
Hysteresis voltage (VH) is the difference between the positive
going voltage (VP) and the negative going voltage (VN) (see FIGURE 3). The digital inputs have programmable logic levels, which
allows the hybrid to be used with different types of commutation
logic with an input voltage range of 5-15 V, such as TTL or CMOS
logic. Pin 6 is the logic power input (VLPI) for the digital circuitry
inside the hybrid. A 0.01 µF, 50 V ceramic capacitor must be
placed between this pin (6) and GND as close to the hybrid
as possible. When using 15 V control circuitry, an external +15
Vdc power supply must be connected between pin 6 of the
hybrid, and GND. The commutation / control circuitry can be as
simple as discrete logic with PWM, or as sophisticated as a
microprocessor or custom ASIC, depending on the system
requirements. FIGURE 4 illustrates a typical interface of the
PWR-82330 with a motor and commutation logic in a Servo-Amp
System. (Refer to AN/H-3 application note for more details.)
INPUTS:
50%
tr
tf
OUTPUTS:
90%
50%
10%
t d (ON)
t d (OFF)
(REFERENCE TABLE 2. ALSO)
FIGURE 2. INPUT/OUTPUT TIMING RELATIONSHIPS
4
sense circuitry to disable the drive if a fault condition occurs (see
FIGURE 6).
SHUT-DOWN INPUT (VSd)
Pin 12 (Vsd) provides a digital shut-down input, which allows the
user to completely turn-off both the upper and lower-output transistors in all 3 phases. Application of a logic ‘1’ to the VSd input
will latch the Digital Control / Protection circuitry thereby turning
off all output transistors. The Digital Control/Protection circuitry
remains latched in the off state and will not respond to signals on
the VL or VU inputs while the VSd has a logic ‘1’ applied. When
the user or the sense circuitry (as in FIGURE 6) returns the VSd
input to a logic ‘0’, and then the user sets the VL and VU inputs
to a logic ‘0’ the output of the Digital Control / Protection circuitry will clear the internal latch. When the next rising edge (see
FIGURE 5) occurs on the VL or VU digital inputs, the outputs
transistors will respond to the corresponding digital input. This
feature can be used with external current limit or temperature
INTERNAL PROTECTION CIRCUITRY
The hybrid contains digital protection circuitry, which prevents inline transistors from conducting simultaneously. This, in effect,
would short circuit the power supply and would damage the output stage of the hybrid. The circuitry allows only proper input signal patterns to cause output conduction. TABLE 3 lists the input/
output timing relationships. If an improper input requested that
the upper and lower transistors of the same phase conduct
together, the output would be a high impedance until removal of
the illegal code from the input of the PWR-82330. A dead time
of 400 nsec minimum should still be maintained between
1
V
2
v
VH
VO
vp
N
FIGURE 3. HYSTERESIS DEFINITION AND CHARACTERISTICS
+15V
+
+28V
+CAP
-CAP
V+
GND
VLPI
CHARGE PUMP
VCC A
VO A
VUA
VLA
DRIVE
A
VSS A
VCC B
POSITION
COMMAND
POSITION
LOOP
AND
COMMUTATION
LOGIC
VUB
VLB
DIGITAL
CONTROL
AND
PROTECTION
CIRCUITRY
HALL
EFFECT
DEVICES
VO B
TANT +
DRIVE
B
MOTOR
VSS B
VCC C
VUC
VLC
VO C
DRIVE
C
VSd
PWR-82330
VSS C
FIGURE 4. TYPICAL INTERFACE WITH A MOTOR AND COMMUTATION LOGIC
5
PWR-82330 POWER DISSIPATION (SEE FIGURE 7)
TABLE 3. INPUT/OUTPUT TRUTH TABLE
INPUTS
OUTPUTS
UPPERS
LOWERS
CONTROL
VUA VUB VUC VLA VLB VLC
VSd
VOA VOB VOC
1
0
0
0
1
0
0
H
L
Z
1
0
0
0
0
1
0
H
Z
L
0
1
0
0
0
1
0
Z
H
L
0
1
0
1
0
0
0
L
H
Z
0
0
1
1
0
0
0
L
Z
H
0
0
1
0
1
0
0
Z
L
H
0
0
1
1
1
0
0
L
L
H
0
1
0
1
0
1
0
L
H
L
0
1
1
1
0
0
0
L
H
H
1
0
0
0
1
1
0
H
L
L
1
0
1
0
1
0
0
H
L
H
1
1
0
0
0
1
0
H
H
L
0
0
0
0
0
0
0
Z
Z
Z
0
0
0
1
1
1
0
L
L
L
1
1
1
0
0
0
0
H
H
H
X
X
X
X
X
X
1
Z
Z
Z
H = High Level, L= Low Level, X=Irrelevant, Z= High Impedance (OFF)
There are three major contributors to power dissipation in the
motor driver: conduction losses, switching losses, and intrinsic
diode losses.
VCC = +28 V (Bus Voltage)
IoA = 3 A, IOB = 7 A (see FIGURE 7)
ton = 20 µs, T = 40 µs (period) (see FIGURE 7)
Ron = 0.13 Ω (on-resistance, see TABLE 2, Io = 5 A, Tc=+25°C)
ts1 = 325 ns, ts2 = 325 ns (see FIGURE 7)
fo = 25 kHz (switching frequency)
VF is an intrinsic diode forward voltage, TABLE 2, Io = 5 A
1. Conduction Losses (PC)
Pc = ( Imotor rms)2 x Ron
the signals at the VU and VL pins; this ensures the complete
turn-off of any transistor before turning on its associated in-line
transistor.
CHARGE PUMP
(IOB - IOA)
2
I motor rms =
IOB - IOB (IOB - IOA) +
I motor rms =
7A - 7A (7A - 3A) +
2
3
(7A - 3A)
2
3
2
ton
T
20us
40us
The PWR-82330 has an internal charge pump circuit to generate
the drive voltage for the high side N-channel MOSFETs. The
charge pump uses an oscillator to charge an external charge pump
capacitor, Cc, from the Vcc supply. This oscillator will pump the
voltage at pin 48 (+cap) of the hybrid higher than Vcc. The hybrid
high side drivers use this voltage to ensure the proper gate drive.
Pc = (3.63 A)2 x (0.13 W)
An external 1 µF, 20% capacitor (Cc) is required between pins 48
and 50. If a polarized capacitor is used, the positive terminal
must be connected to pin 48. The voltage rating of Cc must be
2x the maximum value of VCC.
Ps = [ 28 V ( 3 A (325 ns) + 7 A (325 ns) ) 25 kHz] / 2
1
V UA
2
3
4
5
6
7
8
9
10
11
12
Pc = 1.71 Watts
2. Switching Losses (Ps)
Ps = [ Vcc ( IOA (ts1) + IOB (ts2) ) fo] / 2
Ps = 1.14 Watts
13
14
15
16
17
18
19
1
0
V LA
1
0
1
0
1
0
V LB
1
0
V LC
1
0
V Sd
V Sd
1
0
V OA
V OA
H
Z
L
V OB
H
Z
L
V OC
H
Z
L
V UB
V UC
FIGURE 5. SHUT-DOWN (VSd) TIMING RELATIONSHIPS
6
1
0
H
Z
L
tSd
+VCC
CC
48
INPUT COMMANDS
8
10
COMMUTATION
LOGIC
14
16
21
23
CURRENT
SENSE
CIRCUITRY
12
50
32
39
46
+ 15V
+CAP -CAP VCC A VCC B VCC A
VUA
VLA
V+
VLPI
VUB
VO A
VLB
VUC
PWR-82330
VO B
VLC
VO C
VSd
GND
VSS C
4
6
43,44,45
36,37,38
MOTOR
29,30,31
5,18,19
VSS B
VSS A
26 27 28 33 34 35 40 41 42
RSENSE
FIGURE 6. FUNCTIONAL SHUT-DOWN INPUT USED WITH CURRENT-SENSING CIRCUITRY
3. Intrinsic Diode Losses (Pd)
Permanent damage will result to the motor drive if the user
does not make the following recommended ground connections that will ensure the proper operation of the hybrid.
Pd= Id (avg) x Vd (avg)
Id(avg) = [(IOB + IOA) / 2] / 2 = [(7 A + 3 A) / 2] / 2 = 2.5 A
The V+ and logic grounds are on pins 5,18, and 19 (GND). The
Vss connections for the output stage are on pins 26-28, 33-35
and 40-42 (VSS). To prevent damage to the internal drive circuitry, the differential voltage between GND and VSS must
not exceed ± 3 V max, dc or peak. This includes the combined
voltage drop of the associated ground paths and the voltage
drop across Rsense (see FIGURE 9). For example, a value for
Rsense of 0.1 Ω will give a voltage drop of 1.00 V at 10 A and
allow enough margin for the voltage drop in the ground conductors. Locate Rsense 1" - 2" maximum from the hybrid. It is critical that all ground connections be as short, and of lowest
impedance, as the system allows.
Pd = 2.5 A x 1.25 V
Pd = 3.125 Watts
TRANSISTOR POWER DISSIPATION ( PQ)
To calculate the maximum power dissipation of the output transistor as a function of the case temperature use the following
equation. (Reference FIGURE 8 to ensure you don’t exceed the
maximum allowable power dissipation of each transistor.
C1, C2, and C3 are 0.1 µF ceramic bypass capacitors that supply high frequency spiking. The voltage rating should be 2x the
maximum system voltage. These capacitors should be located as
close to the hybrid as possible. Please note, on FIGURE 9, that
C1, C2, and C3 must go directly from terminal-to-terminal on the
hybrid - do not daisy chain along the power ground return.
PQ = Pc + Ps + Pd
TOTAL HYBRID POWER DISSIPATION (PTOTAL)
To calculate Total Power dissipated in the hybrid use:
6
PTOTAL= ∑ [ PQi ] where i = each transistor
C4 and C5 are 0.01 µF, 50 V ceramic capacitors for power supply decoupling. Locate as close to the hybrid as possible. CC is
a 1 µF, 20% capacitor (either polarized or nonpolarized). If a
polarized cap is used, the positive terminal must be connected
to pin 48 of the hybrid. Voltage rating should be 2x the maximum
system voltage.
i=1
LAYOUT AND EXTERNAL COMPONENTS
Important Information - The following layout guidelines and
required external components are critical to the proper
operation of these motor drives.
Care must be taken to control the regenerative energy produced
by the motor in order to prevent excessive voltage spiking on the
VCC line. Accomplish this by placing a capacitor or clamping
diode between VCC and high power ground return.
7
SWITCHING LOSSES
ton
VCC
IOB
IOA
IO
ts1
t s2
FIGURE 7. OUTPUT CHARACTERISTICS
5.5
OUTPUT CURRENT, IO (amps)
5.0
4.5
4.0
3.5
3.0
2.5
2.0
1.5
1.0
0.5
0.0
30
-55
40
50
60
70
80
90
100
110
120
130
CASE TEMPERATURE, TC (°C)
FIGURE 8. MAXIMUM ALLOWABLE CONDITIONS
OUTPUT CURRENT VS. CASE TEMPERATURE
VCC
8
10
VCC A 46
VUA
VLA
VSS A
5
GND
14
16
18
VO A
VCC B
VUB
23
19
39
C2
VSS B
GND
VO B
21
C1
43,44,45
33,34,35
PWR-82330
VLB
40,41,42
VUC
VCC C
VLC
VSS C
VO C
GND
+CAP
V+
4
48
C4
-CAP
50
CC
36,37,38
32
26,27,28
C3
29,30,31
VLPI
6
RSENSE
C5
C1,C2,and C3=0.01 µF ceramic capacitors
C4 and C5=0.01 µF ceramic capacitors
FIGURE 9. GROUND CONNECTIONS
8
MOUNTING
TABLE 4. PIN ASSIGNMENTS
The PWR-82330 package is designed for direct insertion to a
printed wiring board. The heat transfer in a hybrid is from semiconductor junction to the bottom of the hybrid case. The flatness
and maximum temperature of this mounting surface are critical
to the performance and reliability, because this is the only
method of dissipating the power generated in the hybrid. Use a
mounting surface flatness of 0.004 inches/inch maximum. This
interface can be improved with the use of a thermal compound
or pad.
1.400±0.005
(35.56±0.127)
0.250 MAX
(6.35)
1.200±0.010
(30.48±0.254)
25
0.250±0.010
(6.35±0.254)
26
2.600±0.005
(66.04±0.127)
0.100±0.005 TYP
(2.54±0.127)
24 EQ. SP.
@ 0.100=2.400±0.010
(@ 2.54=60.96±0.254)
0.018±0.002
DIA TYP
(0.457±0.051)
1
PIN NO. 1
CONTRASTING
COLOR BEAD
50
BOTTOM VIEW
SIDE VIEW
NOTES:
1. DIMENSIONS IN INCHES(MM). TOL = ±0.005(±0.127).
2. LEAD CONCENTRATION NUMBERS ARE FOR REFERENCE ONLY.
FIGURE 10. MECHANICAL OUTLINE
9
PIN
FUNCTION
PIN
FUNCTION
1
N/C
50
-CAP
2
N/C
49
N/C
3
N/C
48
+CAP
4
V+
47
N/C
5
GND
46
VC
A
6
VLPI
45
VO
A
7
N/C
44
VO
A
8
VUA
43
VO
A
9
N/C
42
VSS
A
10
VLA
41
VSS
A
11
N/C
40
VSS
A
12
VSd
39
VCC
13
N/C
38
VO
B
14
VUB
37
VO
B
15
N/C
36
VO
B
16
VLB
35
VSS
B
17
N/C
34
VSS
B
18
GND
33
VSS
B
19
GND
32
VCC
20
N/C
31
VO
C
21
VUC
30
VO
C
22
N/C
29
VO
C
23
VLC
28
VSS
C
24
N/C
27
VSS
C
25
N/C
26
VSS
C
B
C
ORDERING INFORMATION
PWR-82330-XX0X
Supplemental Process Requirements:
S = Pre-Cap Source Inspection
L = Pull Test
Q = Pull Test and Pre-Cap Inspection
K = One Lot Date Code
W = One Lot Date Code and PreCap Source
Y = One Lot Date Code and 100% Pull Test
Z = One Lot Date Code, PreCap Source and 100
Blank = None of the Above
Process Requirements:
0 = Standard DDC Processing, no Burn-In (See table below.)
1 = MIL-PRF-38534 Compliant
2 = B*
3 = MIL-PRF-38534 Compliant with PIND Testing
4 = MIL-PRF-38534 Compliant with Solder Dip
5 = MIL-PRF-38534 Compliant with PIND Testing and Solder Dip
6 = B* with PIND Testing
7 = B* with Solder Dip
8 = B* with PIND Testing and Solder Dip
9 = Standard DDC Processing with Solder Dip, no Burn-In (See table below.)
Temperature Grade/Data Requirements:
1 = -55°C to +125°C
2 = -40°C to +85°C
3 = 0°C to +70°C
4 = -55°C to +125°C with Variables Test Data
5 = -40°C to +85°C with Variables Test Data
8 = 0°C to +70°C with Variables Test Data
*Standard DDC Processing with burn-in and full temperature test — see table below.
STANDARD DDC PROCESSING
MIL-STD-883
TEST
METHOD(S)
CONDITION(S)
INSPECTION
2009, 2010, 2017, and 2032
—
SEAL
1014
A and C
TEMPERATURE CYCLE
1010
C
CONSTANT ACCELERATION
2001
A
BURN-IN
1015, Table 1
—
10
NOTES
11
The information provided in this data sheet is believed to be accurate; however,
no responsibility is assumed by Data Device Corporation for its
use, and no license or rights are granted by implication
or otherwise in connection therewith.
Specifications are subject to change without notice.
105 Wilbur Place, Bohemia, New York 11716-2482
For Technical Support - 1-800-DDC-5757 ext. 7420
Headquarters - Tel: (631) 567-5600 ext. 7420, Fax: (631) 567-7358
Southeast - Tel: (703) 450-7900, Fax: (703) 450-6610
West Coast - Tel: (714) 895-9777, Fax: (714) 895-4988
Europe - Tel: +44-(0)1635-811140, Fax: +44-(0)1635-32264
Asia/Pacific - Tel: +81-(0)3-3814-7688, Fax: +81-(0)3-3814-7689
World Wide Web - http://www.ddc-web.com
ILC DATA DEVICE CORPORATION
REGISTERED TO ISO 9001
FILE NO. A5976
C-07/99-500
PRINTED IN THE U.S.A.
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