AD AD9712JP

-
ANALOG DEVICES fAX-ON-DEHAND HOTLINE
W
Page
23
ANALOG
DEVICES
12-Bit,100MSPS
UtAConverters
AD97121AD9713
I
I
FUNCTIONAL
FEATURES
100 MSPS Update Rate
ECL/TTL Compatibility
Low Glitch Impulse: 100 pV-s
Fast Settling: 30 ns to %1 LSB
Low Power: 700 mW
BLOCK DIAGRAM
AD9712/AD9713
APPUCA TlONS
ATE
Signal Reconstruction
Arbitrary Waveform Generators
Digital Synthesizers
Signal Generators
OBS
OLE
GENERAL DESCRIPTION
The AD9712 and AD9713 are I2-bit, high speed digitalto-analog converters constructed in an advanced oxide isolated
bipolar process. The AD9712 is an ECL-compatible device
featUring update rates of 100 MSPS minimum; the TTLcompatible AD9713 will update at 80 MSPS minimum.
Designed for direct digital synthesis, waveform reconstruction,
and high resolution imaging applications, both devices feature
low glitch impulse of 100 pV-s; and fast settling times of 30 ns
to :!:1 LSB. Both units are characterized for dynamic performance, and have excellent harmonic suppression.
~2o)oo
REFERENCEY
OUT
L
o(191
YcONTROL
I AMP IN
TE
The AD9712 and AD9713 are available in 28-pin plastic DIPs
and PLCCs, with an operating temperature range of 0 to + 70°C.
Contact the factory for availability of military-grade devices.
c
~
0
a:
C)
iii
Q' a
Q' Q
;i
w
m:
..
%
~
~
5 ~
C <> ~
61 LATCH ENABLE
!I DIGITAL+V.
rn
221 REFERENCE
~
:2J REFERENCE
;1"
CONTROL
.!!.I CONTROL
m
ANALOG RETURN
GROUND
REFERENCE GROUND
OUT
REFERENCE OUT
191 CONTROL
AMP IN
AMP IN
AMP OUT
REFERENCE
IN
113
,:'
,
'"
51 ANALOG-V.
9
:!
..
Plastic DIPPinout Designations (Top View)
I-Bwo,.,
~
5
a.
%::E
0
~..
~ c:
II!
~
0
0
PLCC Pinout Designations
REV.A
Information furnished by Analog Devices is believed to be accurate and
reliable. However. no responsibility is assumed by Analog Devices for its
use. nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
One Technology Way. P.O. Box 9106. Norwood. MA 02062-9106
Tel: 617/329-4700
Fax: 617/326-8703
Twx: 710/394-6577
We5t CQut
Central
Atlantic:
714/641-9391
214/231-5094
215/643.7790
RNRLOGDEVICES fRX-ON-DEnRND HOTLINE
- Page
2~
AD9712/AD9713
-SPECIFICATIONS
ABSOLUTE MAXIMUM RATINGS!
Positive Supply Voltage (+Vs)(AD9713 Only) . . . . . . . .+6 V
Negative Supply Voltage (-Vs)
(AD9712andAD9713)
7V
DAC Outputs to ANALOG RETURN . . . . . .+0.5V to -2 V
Digital Input Voltages (D1-D12' LATCH ENABLE)
AD9712
0Vto-Vs
AD9713
0Vto+Vs
Internal Reference Output Current. . . . . - 20 JLAto + 500 fLA
Control Amplifier Input Voltage Range . . . . . . . .0Vto -4 V
ControlAmplifierOutputCurrent
.:!:2.5mA
ELECTRICALCHARACTERISTICS(-Vs
= -5.2
(external); R$ET
OBS
Parameter (Conditions)
RESOLUTION
DC ACCURACY
Differential Nonlinearity Q)
Integral Nonlinearity Q)
«<Best Fit" Straight Line)
INITIAL OFFSET ERROR
Zero-SC4UeOffset Error
Full-Scale Gain Error3
Offset Drift Coefficient
REFERENCE/CONTROL AMP
Internal Reference Voltage
Internal Reference Voltage Drift
Amplifier Input Impedance
Amplifier Bandwidth
REFERENCE INPtYf4
Reference Input Impedance
Reference Multiplying Bandwidths
OtITPUT PERFORMANCE
Full-Scale Output Currenr6
Output Compliance Range
Output Resistance
Output Capacitance
Output Update Rate7
Output Settling Time (tST)S
Current Settling
Voltage Settling (RL = 50 fi)
Output Propagation Delay (tpD)9
Glitch Impulse1O
Output Slew Ratell
Output Rise Timeu
Output Fall Timell
REFERENCE IN Voltage Range. . . . . . . . . .-3.7 V to -Vs
Analog Output Current (lOUT or lOUT)
.30 mA
Operating TemperatUre Range
AD9712]NIJP
Oto+70DC
AD9713]N/]P
Oto+70DC
Maximum Junction Temperature2 . . . . . . . . . . . . . . .+ IS0.C
Lead TemperatUre (Soldering, 10 seconds) . . . . . . . . .+ 300DC
Storage TemperatUre Range
.-65°C to + IS0DC
V;+vs
= +5 V(AD9713 Only); CONTROL
AMP
=1.5 kG, unlessotherwisenoted)
Temp
Test
AD9112JN/JP
Level MiD
Typ
12
+ 25"C
Full
+ 25"C
Full
I
VI
I
VI
+25°C
Full
+2sDC
Full
+25OC
I
VI
I
VI
V
+25OC
Full
Full
+25°C
+2SoC
I
I
V
V
V
+25°C
+2SoC
V
V
+ 25°C
+ 25OC
+25°C
+2sDC
+25DC
V
IV
IV
V
IV
+2SoC
+2SoC
+2SoC
+2SoC
+2SoC
+2SOC
+25OC
V
V
V
V
V
V
V
Max
AD9713JNIJP
MiD
Typ
12
OLE
1.2
2.0
4.0
3.0
4.0
1.2
0.5
1.5
5.0
8.5
11.0
0.5
4.0
4.0
0.03
-1.13
-1.11
- 1.26
0.03
- 1.39
-1.41
-1.13
-1.11
300
50
300
3
40
3
40
100
2.5
30
110
30
30
8
100
400
3
2
-2-
Units
Bits
2.0
4.0
3.0
4.0
LSB
LSB
LSB
LSB
TE
1.5
5.0
8.5
11.0
-1.2
2.0
80
2.5
30
90
30
30
11
100
400
3
2
IJoA
IJoA
%
%
p.ArC
- 1.39 V
V
IJoV/oc
kO
kHz
kf!
MHz
20.48
+3
3.0
= -1.2 V
Max
-1.41
300
50
300
20.48
-1.2
2.0
-1.26
IN
+3
3.0
mA
V
kf!
pF
M,SPS
ns
ns
ns
pV-s
V/s
ns
ns
REV.A
- Page
RNRLOGDEVICES fRK-ON-DEHRND HOTLINE
25
AD9712/AD9713
Parameter (Conditious)
DIGITAL INPUTS
Logic "I" Voltage
Logic "0" Voltage
Logic "1" Current
Logic "0" Current
Input Capacitallce
Input SetUp Time (t8)12
Input Hold Time (tiVU
Latch Pulse Width (tLPW)
(Transparent)
AC LINEARITY1.
Spurious-Free Dynamic Range
POWER SUPPL ylS
Positive Supply Current (+5.0 V)
Temp
Test
Level
AD97UJNIjP
MiD
Typ
Max
Full
Full
Full
Full
+ 25°C
+ 25°C
+ 25"C
VI
VI
VI
VI
V
V
V
-1.0
-0.8
-1.7
+25"C
Nominal Power Dissipation
Power Supply
Rejection Ratio (PSRR)16
Mu.
Units
-1.5
0.8
V
V
20
10
20
600
2.0
3
3
3
3
3
3
f.LA
pF
fiS
fiS
V
2.5
4
ns
+25°C
V
-60
-55
dBc
+2S"C
Full
+ 25"C
Full
+25"C
I
VI
I
VI
V
676
+25°C
I
50
OBS
Negative Supply Current (-5.2 V)
AD9713JNIjP
MiD
Typ
10
130
135
160
170
20
23
165
175
mA
mA
mA
mA
mW
350
IJ.AN
726
350
50
OLE
NOTES
'AbsolUte maximum ratings are limiting values to be applied individually, and beyond which the serviceability of the circuit may be impaired.
Functioual operability is DOtnco:ssarily implied. Exposure to absolute maximum rating conditions for an extended period of time may affect device reliability.
2"fypicaI thcrmal impedances: 28-pin plastic DIP 8J/\ = 4row;
8JC = 7"CIW; 28-pin PLCC 9,/\ = 48°C/Wj 8Jc = IOOCJW.
3Measured as error of me ratio of full-scale current to current throush RSET (160 IJ.Anominal); ratio is nominally 128.
4Pu11-scale variattous &moor devices are more severe when driving REFERENCE IN directly.
'Frequ~
at which a 3 dB reduction in output of DAC is observed; RL = 50 OJ 50% modulation at midscale.
when using internal amplifier.
6Based on Ips = 128 (V~)
70utpUt settJin& to 0.1%.
'Measured at midscale transition, (0 :to.O24%.
'Measured from falling edge of LATCH ENABLE signal to 50% point of full.scale transition.
"'Glitch impuJlie combines me absolute value of positive and negarive transitions operating in latched mode.
uMcasurcd wim RL = SO 0 and DAC operating in latched mode.
"Data must remain stable prior (0 falling edge of LATCH ENABLE signal for specified time.
13Data must remain stable after rising edge of LATCH ENABLE signal for specified time.
rate s50
"Supply
voltages should remain stable within :t5% for normal operation.
It
:t5%
of
output
frequency
= 5 MHz.
14Update
16Mcasured
MSPS;
+ V s (AD9713
only)
TE
and
-
V s (AD9712
or AD9713)
using
external
reference.
Specifications subject to chance withoUt ponce.
EXPLANATION
OF TEST LEVELS
ORDERING GUIDE
Level
I
II
-
-
100% production
tested.
100% production tested at + 25°C. and sample tested at
specifiedtemperatures.
III - Sampletested only.
IV - Parameteris guaranteedby design and
characterizationtesting.
V
Parameter is a typical value only.
VI
- All devices arc 100% production
REV. A
Model
Description
AD9712JN
AD9712JP
ECL-Compatible Plastic DIP
ECL-Compatible PLCC
Package
Option.
N-28
P-28A
AD97I3JN
AD9713JP
ITL-Compatible Plastic DIP
ITL-Compatib1e PLCC
N-28
P-28A
*N
tested at +25°C. 100%
production tested at temperatUre extremes for extended
temperature devices; sample tested at temperature
exttcmes for commercial/industrial devices.
-3-
= Plastic
DIP; P
= Plastic
Leaded Chip Carrier.
ANALOGDEVICES fAX-ON-DEMAND HOTLINE
- Page 26
AD9713/AD9713
AD911Z1AD9713
PIN DESCRIPTIONS
Pia
Fanctioll
No.
Name
1-10
D2-D11
Ten of twelve digital input bits.
11
D12 (LSB)
Least Significant Bit (LSB) of digital input word.
12
13
DIGITAL -Vs
ANALOG RETURN
14
loUT
Analog current output; full-scale output occurs with digital
inputs at all "I."
15
ANALOG -Vs
One of two negative analog supply pins; nominally -5.2 V.
16
loUT
Complementary analog current output; zero scale output occurs
with digital inputs at all "1."
One of two negative digital supply pins; nominally -5.2 V.
Analog ground retUrn. This point and the reference side of the
DAC load resistors should be connected to the same potential
(nominally ground).
OBS
17
REFERENCE IN
Normally connected to CONTROL AMP OUT (Pin 18). Direct
line to DAC current switch network. Voltage changes at this
point have a direct effect on the full-scale output. Full-scale
current output"" 128 (Reference voltageIRsET) when using
internal amplifier.
18
CONTROL AMP OUT
Normallyoonnected to REFERENCE IN (pin 17). Output of
internal control amplifier, which provides a temperature
oompensated drive level to the current switch network.
19
CONTROL AMP IN
Normally connected to REFERENCE OUT (pin 20) if not
connected
OLE
to external reference.
Full-scale current
out
=
128
(Reference voltageIRsET) when using internal amplifier.
20
REFERENCE OUT
Normally connected to CONTROL AMP IN (pin 19). Internal
voltage reference, nominally -1.26 V.
21
22
23
DIGITAL -Vs
REFERENCE GROUND
One of two negative digital supply pins; nominally
DIGITAL +Vs
Positive digital supply pin; used only on the AD9713; nominally
+5V.
24
RsET
Connection for external resistance reference. Full-scale current
out
128 (Reference voltagelRsET) when using internal
amplifier.
25
26
27
28
ANALOG -Vs
LATCH ENABLE
DIGITAL GROUND
One of two negative analog supply pins; nominally -5.2 V.
D1 (MSB)
- 5.2 V.
Ground return for the internal voltage reference and amplifier.
TE
=
Transparent latch coDtrolline.
Digital ground retUrn.
Most Significant Bit (MSB) of digital input word.
LATCH
ENABLE
LATCH ENABLE
OUTPUT
ERROR
DATA HOUrS
OUTPUT
t..- -
t.--
./
t ..
I ST
t I'D
-
LATCHPULSEWIOTIf
INPUTSETUPTIIE
INPUT HOLD TIME
OUT'POT SETTUHO TIME
OUT'POT
PROPAGA11ON
DELAY
AD97121AD9713 Timing Diagram
-4-
REV.
---~
A
RNRLOGDEVICES fRX-ON-DEHRND HOTLINE
- Page
27
AD9712/AD9713
THEORY AND APPUCATIONS
The AD9712 and AD9713 high speed digital-to-analog conveners utilize Most Significant Bit (MSB) decoding and segmentation techniques to reduce glitch impulse and maintain linearity
without trimming.
greater accuracy or better temperature stability is required, an
external reference can be utilized. The AD589 reference shown
in Figure I features :t 10 ppm?C drift over temperatUres from 0
to +70°C.
As shown in the functional block diagram, the design is based
on four main subsections: the DecoderlDriver circuits, the
Transparent Latches, the Switch Network and the Control
Amplifier. An internal band-gap reference is also included to
allow operation with a minimum of external components.
A09712
A09713
:II1)CON'TROl
4MP IN
R,
::11kl)
Digital Inputs
The AD9712 employs single-cnded ECL-compatible inputs for
data inpUtS DI-D12 and LATCH ENABLE. The internal ECL
midpoint reference is designed to match 10K ECL device
thresholds. On the AD9713, a TTL translator is added at
each input; with this exception, the AD9712 and AD9713 are
identical.
-VI
Figure 1. Use of A 0589 8S External Reference
OBS
Two modes of multiplying operation are possibl~ with the
AD97121AD9713. Signals with bandwidths up to 400 kHz and
input swings from -0.1 V to -1.2 V can be applied to the
CONTROL AMP input as shown in Figure 2. Because the control amplifier is internally compensated, the 0.1 J.LFcapacitor at
Pin 17 can be eliminated to maximize the multiplying bandwidth. However, it should be noted that settling time for
changes to the digital inputs will be degraded.
In the DecoderlDriver section, the four MSBs (DcDJ are
decoded to 15 "thermometer code" lines. An equalizing delay is
included for the eight Least Significant Bits (LSBs) and
LATCH ENABLE. This delay minimizes data skew, and data
setup and hold times at the latch inputs; this is important when
operating the latches in the transparent mode. Without the
delay, skew caused by the decoding circuits would degrade
glitch impulse.
The latches operate in their transparent mode when LATCH
ENABLE (Pin 26) is at logic level "0." The latches can be used
to synchronize data to the current switches by applying a narrow
LATCH ENABLE pulse with proper data setup and hold times
as shown in the timing diagram. With an external transparent
latch at each data input clocked out of phase with the DAC, the
AD97121AD9713 operates in a master slave (edge-triggered)
mode.
OLE
.IJ.6Vlo.l.2V
181l
Although the AD97121AD9713 chip is designed to provide isolation from digital inputs to the outputs, some coupling of digital
transitions is inevitable, especially with TTL or CMOS inputs
applied to the AD9713. Digital feedthrough can be reduced by
forming a low-pass filter using a resistor in series with the
capacitance of each digital input.
References
As shown in the functional block diagram, the internal band-gap
reference, control amplifier and reference input are pinned out
for maximum user flexibility when setting the reference.
Figure 2. Low Frequency Multiplying Circuit
The REFERENCE IN pin can also be driven directly for wider
bandwidth multiplying operation. The analog signal for this
mode of operation must have a signal swing in the range of
-4 V to -5.2 V. This can be implemented by capacitively coupling into REFERENCE IN an ac signal and establishing a de
bias of -4.0 V to -5.2 V, as shown in Figure 3; or by driving
REFERENCE IN with a low impedance op amp whose signal
swing is limited to the stated range.
When using the internal reference, REFERENCE OUT (Pin 20)
should be connected to CONTROL AMP IN (pin 19). CONTROL AMP OUT (pin 18) should be connected to REFERENCE IN (Pin 17) through an 18 n resistor. A 0.1 J.LFceramic
capacitor from Pin 17 to -Vs (pin 15) improves settling by
decoupllng switching noise from the current sink base line. A
reference current cell provides feedback to the control amp by
sinking current through Rsn (Pin 24).
AD9712
AD9713
4k1l
Full-scale output current is determined by the voltage at CONTROL AMP IN (VREF)and Rsn according to the
equation:
lOUT IPS)
ANAl~
>
O.I~FI
1.2k11
= VREFIRsET x 128.
-V.
The internal reference is nominally - 1.26 V with a tolerance of
:t 10% and typical drift over temperature of 300 J.L
vrc. If
REV. A
TE
-vo
Figure 3. Wideband Multiplying Circuit
-5-
ANALOG DEVICES fAX-ON-DEMAND HOTLINE
- Page 28
AD9712/AD9713
the DAC output as shown in Figure 5. Reducing DAC full-scale
outpUt current degrades both linearity and settling time; therefore, the current divider method is preferable.
Outputs
The Switch Network controls complementary current outputs
lOUT and lOUT' As indicated earlier, DcD. are decoded into IS
"thermometer code" lines which drive matched current sources.
Ds and D6 control weighted current sources; and D7-D12 are
applied to the R-2R network.
.V."'
This segmentation reduces frequency domain errors due to'
glitch impulse. Current is steered to either lOUT or lOUT in proportion to the digital input code. The sum of the two currents is
always equal to the full-scale output current minus one LSB.
The current output can be converted to a voltage by resistive
loading as shown in Figure 4. Both louT and lOUT should be
loaded equally for best overall performance. The voltage which
is developed is the product of the output current and the value
of the load resistor.
R"
v"'"
RL
OBS
eeL
DRIVE
LOGIC
=-5V
RL
Figure 5. IN Conversion
O.'"F*
-uv
V'OLL 8C.ILE ~ .5V
Yu.a""
Using Current Feedback Amp
The DAC output is not clamped at virtual ground in this configuration because of the series resistance RFF' The value of RFF is
selected according to the equation:
OLE
RLIFS
-
=
RFF
-R
V Full Seal<
FB
V Full Scale
R FB
+ I OFF R L
+ I OFF
TE
As an example, assume the following conditions:
RL 0=50 n
RFB = 1.5 kG
IFs = 20.48 mA
I OFF---VZerosC'.oIe- - 33. mA
RFB
Given these conditions,
RFF
=
103.6 fl
Power and Grounding
Maintaining low noise on power supplies and ground is critical
for obtaining optimum results with the AD9712 or AD9713.
DACs are most often used in circuits which are predominantly
digitaL To preserve 12-bit performance, especially at conversion
speeds up to 100 MSPS, special precautions are necessary for
power supplies and grounding.
S'lSTI!M
CAOuICI
Figure 4. Typical Resistive Load Connection
When operating at the nominal full.scale current of 20.48 mA,
the voltage swing will be from 0 to -1.024 V across SOfl resistors. Bipolar outputs are possible by sourcing a current equal to
half the DAC full-scale current into the load resistor.
Ideally, the DAC should have a separate analog ground plane.
All ground pins of the DAC, as well as reference and analog
output components, should be tied directly to this analog
ground plane. The DAC's ground plane should be connected to
the system ground plane at a single point.
Ferrite beads, along with high frequency, low inductance decoupiing capacitors, should be used for the supply connections ro
isolate digital switching currents from the DAC supply pins.
Separate isolation networks for the digital and analog supply
connections will further reduce supply noise coupling to the
oUtput.
Molded socket assemblies should be avoided even when prototyping circuits with the AD9712 or AD9713. When the DAC
cannot be directly soldered into the board, individual pin sockets such as AMP #6-330808-0 (knock-out end), or #60330808-3
(open end) should be used. These have much less effect on
interlead capacitance than do molded assemblies.
An alternate method of converting the current oUtput to voltage
is by driving the summing node of an operational amplifier
directly with a feedback resistor selected according [0 "the
equation:
RFS = VOUT(FSI / lOUT (FS)
A current feedback amplifier such as the AD9610 offers signifi.
cantly faster settling and greater bandwidth than a conventional
voltage feedback op amp. The feedback resistor for the AD9610
must be 1.5 kfl or greater to maintain stability. This value for
RFB' along with the 20.48 mA full-scale output current, results
in a full-scale output of 30 V, which exceeds the output range of
the AD9610.
Full-scale output voltage can be reduced by either reducing the
DAC's full-scale output current, or by using a current divider at
-6-
REV. A
- Page
ANALOGDEVICES fAX-ON-DEMAND HOTLINE
~9
AD9712/AD9713
-3S
-3S
-40
-40
-45 >-------
-45
-60
-50
.1!-55
..
...1!-55
1MHz SINE WAVE
-4iO
10
-75
-35
-40
-45
-45
-50
-so
i
-75
~
REFER
I
OUT
Reference
~
+
-
CONTROL
138 CURRENT
SOUR
~~lLJ
,.
r---1
TE
60 100
Reference Input
Output
ECLV-
-li.2Y
Control Amplifier Input
2R
II
,,
AD9713 Harmonic Distortion Ys. Update Rate
~yf
2R
r
,
,
20
40
60
UPDATERATE(MSPS)
-7510
60 100
~~
II
-
-70
I -..
I_-tii
~
60 100
i--------
.. -60 /2NDHARMONIC
~~:'~-:RMONIC
-65
SADHARMONIC
-
AD9712 Harmonic Distortion vs. Update Rate
,-I
60
.1!-55
20
40
80
UPDATERATE(MSPS)
10
i
10
OLE
HARMONIC
AT NOI~E F1.00R
I
AD9713 Harmonic Distortion vs. Update Rate
-40
-7\)
-
,/
-70
45
OBS
-
2ND, 3RD, AND
4TH HARMONICS
-65
AD9712 Harmonic Distortion vs. Update Rate
i-55
-4iO
-S L 3RO
CSFDR)
2ND, 3RD, AND
,/ AT NOISE F1.00R
I
I
80 100
20
40
80
UPDATE RATE (lISPS)
-7\)
II
~
-60
i
L 4TH HARMONICS
-M
-7$
SPURIOUS-FREE
DYNAMIC RANGE
"
Full-Scale Current Control Loop
2ft
"
2ft
R
-li.2V
Control Amplifier Output
I"",
leu.
9
9
2.5kU
3OpI'
ECL Input Buffer
"-
9
>2_1
-
TT1.
IN
-$.2Y
R-2R DAC
(for 6 LSBs)
ITL Input Buffer
-Va
Output Circut
AD97121AD9713 Equivalent
REV. A
-7-
Circuits
-
ANALOGDEVICES FAX-ON-DEMANDHOTLINE
30
Page
AD971VAD9713
OUTLINE DIMENSIONS
Dimensions shown in inches and (rnm)
2S-Pin Plastic DIP (Suffix N)
0'>
ex>
a
J
;I
~: : : : : : : : : : : ]~
~I~=
-11~._'~
~
~
(.)
1.38011.565 (35.101:1S.70)
H
~
OBS
0.014111.112%
(0.35610'-)
D.IOOIISC
(2.5411$C)
-10.01510.060
!
TOP VIEW
(NOIIO-)
~
~
11
t
Chip Carrier
j.
OLE
I
ae~
f
0.-430
...L (UI,:o.82)
0.lIIIO IISC
TII.Z7j)
...L 0.0131\).021
T
(o.331G..53)
:. LIO.Q2jIIO.03Z
IT (D.",,)
II
L..J OASOlG.U L.J L.J(IU3i1t.S8)
U
U
0---112.32112.57)
(Suffix P)
1
"
IZ
IUI)
MlN
(1.77 MAX)
LI- t ~~~:o;:~ ,..,
~
+
0.1511
t
D.70""X
2S-Pin Plastic Leaded
,(:4
~
ii
+
-
0.0"""-°25
-
0.025I0.O«I(0.&411.01)
(o..3IW.63)
-o._nO(2.11112.79}
-I
O.le$;o.,OO
1(4.1"4.57)
TE
4.
v>
::>
~
0
UJ
IZ
a:
0..
-8-
REV. A
--~