AD AD53519JP

PRELIMINARY TECHNICAL DATA
a
Dual Ultrafast
Voltage Comparator
AD53519
Preliminary Technical Data
FEATURES
Robust Input Protection
300 ps Propagation Delay Input to Output
75 ps Propagation Delay Variation
Differential ECL Compatible Outputs
Differential Latch Control
Power Supply Rejection Greater than 70 dB
200ps Minimum Pulse Width (Bandwidth > 2.5
GHz)
5 Gbps Toggle Rate
Typical Output Rise/Fall of 150 ps
APPLICATIONS
Automatic Test Equipment
High Speed Instrumentation
Scope & Logic Analyzers Front End
Window Comparators
High Speed Line Receivers
Threshold Detection
Peak Detection
High Speed Triggers
Patient Diagnostics
Disk Drive Read Channel Detection
Hand-Held Test Instruments
Zero Crossing Detectors
Line Receivers & Signal Restoration
Clock Driver
Upgrade for SPT9689 Designs
Upgrade for AD96687 Designs
GENERAL DESCRIPTION
The AD53519 is an ultrafast voltage comparator fabricated on
ADI’s proprietary XFCB process. The device features 300 ps
propagation delay with better than 75 ps overdrive dispersion.
Dispersion is a particularly important characteristic of high
speed comparators. It is a measure of the difference in
propagation delay under differing overdrive conditions.
FUNCTIONAL BLOCK DIAGRAM
NONINVERTING
INPUT
INVERTING
INPUT
+
Q OUTPUT
-
/Q OUTPUT
LATCH ENABLE
INPUT
/LATCH ENABLE
INPUT
Figure 1
mode range from –2.0 V to +3.0 V. Outputs are
complementary digital signals fully compatible with ECL 10 K
and 10 KH logic families. The outputs provide sufficient drive
current to directly drive transmission lines terminated in 50 Ω
to –2 V. A latch input is included which permits tracking,
track-hold, or sample-hold modes of operation.
The AD53519 is available in a 20-lead PLCC package.
A fast, high precision differential input stage permits consistent
propagation delay with a wide variety of signals in the common
REV. Pr J July 22, 2002
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 that 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 U.S.A.
Tel: 781/329-4700
Fax: 781/326-8703
www.analog.com
© Analog Devices, Inc., 2002
PRELIMINARY TECHNICAL DATA
AD53519
AD53519 ELECTRICAL CHARACTERISTICS (VCC = +5.0V, VEE = -5.2V, TA = +25°C unless otherwise noted)
PARAMETER
SYMBOL
CONDITION
Min
Typ
Max
UNITS
-10.0
±3.0
10.0
mV
mV
INPUT
CHARACTERISTICS
Input Offset Voltage
Input Offset Voltage
Channel Matching
Offset Voltage Tempco
Input Bias Current
Input Bias Current Tempco
Input Offset Current
Input Voltage Range
Input Capacitance
Input Resistance
Input Resistance,
Differential Mode
Input Resistance, Common
Mode
Input Common Mode Range
Open Loop Gain
Common Mode Rejection
Ratio
Input Differential Voltage
Hysteresis Skew
VOS
DVOS/dT
IBC
10.0
±16
±1.0
-2.0
±25.0
±3.0
3.0
CIN
Rins
40
µV/°C
µA
nA/°C
µA
V
pF
kΩ
kΩ
kΩ
VCM
CMRR
-2.0
3.0
60
70
VCM = -1.0 V to +3.0 V
V
dB
dB
V
mV
ENABLE INPUT
CHARACTERISTICS
Latch Enable Common
Mode Range
Latch Enable Differential
Input Voltage
Input HIGH Voltage
Input LOW Voltage
Input HIGH Current
Input LOW Current
Latch Set-up Time
Latch to Output Rise Delay
Latch to Output Fall Delay
Latch Pulse Width
Latch Hold Time
VLCM
-2.0
0
V
VLD
0.4
2.0
V
VIH
VIL
tS
tPLOH
tPLOL
tPL
tH
@ 0.0 Volts
@ -2.0 Volts
250 mV Over Drive
250 mV Over Drive
250 mV Over Drive
250 mV Over Drive
250 mV Over Drive
VOH
VOL
ECL 50 Ohms to –2.0 V
ECL 50 Ohms to –2.0 V
V
V
µA
µA
ps
ps
ps
ps
ps
150
375
375
150
0
OUTPUT
CHARACTERISTICS
Output Voltage - High Level
Output Voltage - Low Level
SWITCHING
PERFORMANCE
Propagation Delay – Input
to Output – Rise
Propagation Delay – Input
to Output – Fall
REV. Pr J July 22, 2002
-1.00
-1.95
-0.81
-1.54
V
V
tPDR
300
ps
tPDF
300
ps
- 2 -
PRELIMINARY TECHNICAL DATA
AD53519
Propagation Delay – Input
to Output – Rise
Propagation Delay – Input
to Output – Fall
Propagation Delay –
Tempco
Rise Time
Fall Time
Equivalent Bandwidth
Toggle Rate
Prop Delay vs. Duty Cycle
Prop Delay vs. Duty Cycle
Slow Edge
Prop Delay vs. Over Drive
(20mV to 1.5V)
Prop Delay Skew
Dispersion - Slew Rate
Within Device Skew,
Channel to Channel Prop
Delay Match
Prop Delay Dispersion
Overdrive
Prop Delay Dispersion
Common Mode Voltage
Prop Delay Dispersion Input
Slew Rate
Prop Delay Dispersion Input
Duty Cycle
Prop Delay Dispersion Input
Pulse Width
Unit to Unit Prop Delay
Minimum Pulse Width - Pos
Minimum Pulse Width Neg
tPDR
20 mV Over Drive
375
ps
tPDF
20 mV Over Drive
375
ps
2
ps/°C
150
150
2500
5
10
20
ps
ps
MHz
Gbps
ps
ps
75
ps
25
ps
ps
ps
tR
tF
BW
20% to 80%
20% to 80%
ps
ps
ps
ps
ps
PWH
PWL
ps
ps
ps
200
200
POWER SUPPLY
Positive Supply Current
Negative Supply Current
Positive Supply Voltage
Negative Supply Voltage
Power Dissipation
Power Dissipation
Power Supply Sensitivity –
VCC
Power Supply Sensitivity –
VEE
IVCC
IVEE
VCC
VEE
@ +5.0 Volts
@ -5.2 Volts
Dual
Dual
Dual, Without Load
Dual, With Load
PSSVCC
550
70
mA
mA
V
V
mW
mW
dB
PSSVEE
70
dB
NOTES:
1.
2.
Under no circumstances should the input voltages exceed the supply voltages
REV. Pr J July 22, 2002
- 3 -
4.75
-4.96
5.0
-5.2
5.25
-5.45
PRELIMINARY TECHNICAL DATA
AD53519
ABSOLUTE MAXIMUM RATINGS
Supply Voltages
Positive Supply Voltage (VCC to GND)............... –0.5V to +6.0V
Negative Supply Voltage (VEE to GND) ..............-6.0V to +0.5V
Ground Voltage Differential................................ –0.5V to +0.5V
Input Voltages
Input Common Mode Voltage ............................. –2.0V to +3.0V
Differential Input Voltage ................................... –3.0V to +3.0V
Input Voltage, Latch Controls .................................... VEE to 0V
Output
Output Current.................................................................... 30mA
Temperature
Operating Temperature, ambient ............................ 0°C to +70°C
Operating Temperature, junction..................................... +150°C
Storage Temperature Range ............................. –65°C to +150°C
Lead Temperature (10 sec) .............................................. +300°C
Stress above those listed under "Absolute Maximum Ratings" may cause permanent damage
to the device. This is a stress rating only and functional operation of the device at these or any
other conditions above those indicated in the operational sections of this specification is not
implied. Exposure to absolute maximum rating conditions for extended periods may affect
device reliability.
ORDERING GUIDE
MODEL
AD53519JP
REV. Pr J July 22, 2002
TEMP
Package
RANGE
Description
o
0/+70 C
PLCC-20
- 4 -
PRELIMINARY TECHNICAL DATA
AD53519
AD53519 PIN DESCRIPTION
11
12
13
+INA
NC
+INB
-INB
REV. Pr J July 22, 2002
3
2
/QB
10
AD53519 PIN CONFIGURATION
1
20
19
PIN 1
IDENTIFIER
GND 4
LEA 5
AD53519
NC 6
TOP VIEW
(Not to Scale)
/LEA 7
VEE 8
NC = NO CONNECT
Figure 2
- 5 -
9
10
11
12
13
-INB
VEE
-INA
QB
NC
8
9
20
QB
NC
/LEA
GND
/QB
NC
6
7
18
19
+INB
GND
LEA
NC
LEB
/QA
4
5
16
17
QA
/QA
Function
Positive Supply Terminal.
One of two complementary inputs for channel
B Latch Enable. In the “compare” mode
(logic LOW), the output will track changes at
the input of the comparator. In the “latch”
mode (logic HIGH), the output will reflect the
input state just prior to the comparator being
placed in the “latch” mode. LEB must be
driven in conjunction with /LEB.
No Connect. Leave pin unconnected.
One of two complementary inputs for channel
B Latch Enable. In the “compare” mode
(logic HIGH), the output will track changes at
the input of the comparator. In the “latch”
mode (logic LOW), the output will reflect the
input state just prior to the comparator being
placed in the “latch” mode. /LEB must be
driven in conjunction with LEB.
Analog ground.
One of two complementary outputs for channel
B. /QB will be at logic LOW if the analog
voltage at the NONINVERTING INPUT is
greater than the analog voltage at the
INVERTING INPUT (provided the
comparator is in the “compare” mode). See
LATCH ENABLE channel B for additional
information
One of two complementary outputs for channel
B. QB will be at logic HIGH if the analog
voltage at the NONINVERTING INPUT is
greater than the analog voltage at the
INVERTING INPUT (provided the
comparator is in the “compare” mode). See
LATCH ENABLE channel B for additional
information
-INA
3
PIN# Name
14
VCC
15
/LEB
Function
No Connect. Leave pin unconnected.
One of two complementary outputs for channel
A. QA will be at logic HIGH if the analog
voltage at the NONINVERTING INPUT is
greater than the analog voltage at the
INVERTING INPUT (provided the
comparator is in the “compare” mode). See
LATCH ENABLE channel A for additional
information
One of two complementary outputs for channel
A. /QA will be at logic LOW if the analog
voltage at the NONINVERTING INPUT is
greater than the analog voltage at the
INVERTING INPUT (provided the
comparator is in the “compare” mode). See
LATCH ENABLE channel A for additional
information.
Analog ground.
One of two complementary inputs for channel
A Latch Enable. In the “compare” mode
(logic HIGH), the output will track changes at
the input of the comparator. In the “latch”
mode (logic LOW), the output will reflect the
input state just prior to the comparator being
placed in the “latch” mode. /LEA must be
driven in conjunction with LEA.
No Connect. Leave pin unconnected.
One of two complementary inputs for channel
A Latch Enable. In the “compare” mode
(logic LOW), the output will track changes at
the input of the comparator. In the “latch”
mode (logic HIGH), the output will reflect the
input state just prior to the comparator being
placed in the “latch” mode. LEA must be
driven in conjunction with /LEA.
Negative Supply Terminal
Inverting analog input of the differential input
stage for channel A. The INVERTING A
INPUT must be driven in conjunction with the
NONINVERTING A INPUT.
Noninverting analog input of the differential
input stage for channel A. The
NONINVERTING A INPUT must be driven
in conjunction with the INVERTING A
INPUT.
No Connect. Leave pin unconnected.
Noninverting analog input of the differential
input stage for channel B. The
NONINVERTING B INPUT must be driven in
conjunction with the INVERTING B INPUT.
Inverting analog input of the differential input
stage for channel B. The INVERTING B
INPUT must be driven in conjunction with the
NONINVERTING B INPUT.
+INA
PIN# Name
1
NC
2
QA
18
GND
17
LEB
16
NC
15
/LEB
14
VCC
PRELIMINARY TECHNICAL DATA
AD53519
TIMING INFORMATION
The timing diagram is presented to illustrate the AD53519 compare and latch features.
SYSTEM TIMING DIAGRAM
/LATCH ENABLE
50%
LATCH ENABLE
tS
tPL
tH
DIFFERENTIAL
INPUT VOLTAGE
V IN
VREF ± VOS
V OD
t PLOH
tPDL
Q OUTPUT
50%
tF
tPDH
50%
/Q OUTPUT
tR
tPLOL
Figure 3
Terms used in timing diagrams:
INPUT TO OUTPUT HIGH
tPDH
DELAY
tPDL
INPUT TO OUTPUT LOW
DELAY
tPLOH
LATCH ENABLE TO
OUTPUT HIGH DELAY
tPLOL
LATCH ENABLE TO
OUTPUT LOW DELAY
tH
MINIMUM HOLD TIME
tPL
tS
MINIMUM LATCH
ENABLE PULSE WIDTH
MINIMUM SETUP TIME
tR
OUTPUT RISE TIME
tF
OUTPUT FALL TIME
VOD
VOLTAGE OVERDRIVE
REV. Pr J July 22, 2002
The propagation delay measured from the time the input signal crosses the reference (±
the input offset voltage) to the 50% point of an output LOW to HIGH transition
The propagation delay measured from the time the input signal crosses the reference (±
the input offset voltage) to the 50% point of an output HIGH to LOW transition
The propagation delay measure from the 50% point of the Latch Enable signal LOW to
HIGH transition to the 50% point of an output LOW to HIGH transition
The propagation delay measured from the 50% point of the Latch Enable signal LOW
to HIGH transition to the 50% point of an output HIGH to LOW transition
The minimum time after the negative transition of the Latch Enable signal that the
input signal must remain unchanged in order to be acquired and held at the outputs
The minimum time that the Latch Enable signal must be HIGH in order to acquire and
input signal change
The minimum time before the negative transition of the Latch Enable signal that an
input signal change must be present in order to be acquired and held at the outputs
The amount of time required to transition from a LOW to HIGH output as measured at
the 20 and 80% points
The amount of time required to transition from a HIGH to LOW output as measured at
the 20 and 80% points
The difference between the differential input and reference input voltages
- 6 -
PRELIMINARY TECHNICAL DATA
AD53519
comparator can be used to recover the distorted waveform while
maintaining a minimum of delay.
APPLICATIONS INFORMATION
The AD53519 comparators are very high speed devices.
Consequently, high speed design techniques must be
employed to achieve the best performance. The most critical
aspect of any AD53519 design is the use of low impedance
ground plane. A ground plane, as part of a multilayer board,
is recommended for proper high speed performance. Using a
continuous conductive plane over the surface of the circuit
board can create this, only allowing breaks in the plane for
necessary current paths. The ground plane provides a low
inductance ground, eliminating any potential differences at
different ground points throughout the circuit board caused
by “ground bounce”. A proper ground plane also minimizes
the effects of stray capacitance on the circuit board.
OPTIMIZING HIGH SPEED PERFORMANCE
As with any high speed comparator or amplifier, proper design
and layout techniques should be used to ensure optimal
performance from the AD53519. The performance limits of
high speed circuitry can easily be a result of stray capacitance,
improper ground impedance or other layout issues.
Minimizing resistance from source to the input is an important
consideration in maximizing the high speed operation of the
AD53519. Source resistance in combination with equivalent
input capacitance could cause a lagged response at the input,
thus delaying the output. The input capacitance of the
AD53519 in combination with stray capacitance from an input
pin to ground could result in several picofarads of equivalent
capacitance. A combination of 3 kΩ source resistance and 5 pF
of input capacitance yield a time constant of 15ns, which is
significantly slower than the sub 500 ps capability of the
AD53519. Source impedances should be significantly less than
100 Ω for best performance.
It is also important to provide bypass capacitors for the power
supply in a high speed application. A 1µF electrolytic bypass
capacitor should be placed within 0.5 inches of each power
supply pin to ground. These capacitors will reduce any
potential voltage ripples from the power supply. In addition,
a 10nF ceramic capacitor should be placed as close as
possible from the power supply pins on the AD53519 to
ground. These capacitors act as a charge reservoir for the
device during high frequency switching.
Sockets should be avoided due to stray capacitance and
inductance. If proper high speed techniques are used, the
AD53519 should be free from oscillation when the comparator
input signal passes through the switching threshold.
The LATCH ENABLE input is active LOW (latched). If the
latching function is not used, the LATCH ENABLE input
should be grounded (ground is an ECL logic HIGH). The
complimentary input, /LATCH ENABLE, should be tied to
–2.0 V to disable the latching function.
COMPARATOR PROPAGATION DELAY
DISPERSION
Occasionally, one of the two comparator stages within the
AD53519 will not be used. The inputs of the unused
comparator should not be allowed to “float”. The high
internal gain may cause the output to oscillate (possibly
affecting the other comparator which is being used) unless the
output is forced into a fixed state. This is easily
accomplished by insuring that the two inputs are at least one
diode drop apart, while also appropriately connecting the
LATCH ENABLE and /LATCH ENABLE inputs as
described above.
The AD53519 has been specifically designed to reduce
propagation delay dispersion over an input overdrive range of
100 mV to 1 V. Propagation delay dispersion is the change in
propagation delay which results from a change in the degree of
overdrive (how far the switching point is exceeded by the
input). The overall result is a higher degree of timing accuracy
since the AD53519 is far less sensitive to input variations than
most comparator designs.
Propagation delay dispersion is a specification, which is
important in critical timing application such as ATE, bench
instruments and nuclear instrumentation. Dispersion is defined
as the variation in propagation delay as the input overdrive
conditions are changed. For the AD53519 dispersion is
typically 50 ps as the overdrive is changed from 100 mV to 1 V.
This specification applies for both positive and negative
overdrive since the AD53519 has equal delays for positive and
negative going inputs.
The best performance will be achieved with the use of proper
ECL terminations. The open-emitter outputs of the AD53519
are designed to be terminated through 50Ω resistors to –2.0
V, or any other equivalent ECL termination. If a –2.0 V
supply is not available, an 82Ω resistor to ground and a 130Ω
resistor to –5.2 V provides a suitable equivalent. If high
speed ECL signals must be routed more than a centimeter,
microstrip or stripline techniques may be required to insure
proper transition times and prevent output ringing.
The 50 ps propagation delay dispersion of the AD53519 offers
considerable improvement of the 100 ps dispersion of other
similar series comparators.
Clock Timing Recovery
Comparators are often used in digital systems to recover clock
timing signals. High-speed square waves transmitted over a
distance, even tens of centimeters, can become distorted due to
stray capacitance and inductance. Poor layout or improper
termination can also cause reflections on the transmission line,
further distorting the signal waveform. A high-speed
REV. Pr J July 22, 2002
- 7 -
PRELIMINARY TECHNICAL DATA
AD53519
PROPAGATION DELAY DISPERSION
The customary technique for introducing hysteresis into a
comparator uses positive feedback. The major problems with
this approach are that the amount of hysteresis varies with the
output logic levels resulting in a hysteresis that is not
symmetrical around zero.
1.5 V OVERDRIVE
INPUT VOLTAGE
20 mV OVERDRI VE
Another method to implement hysteresis is generated by
introducing a differential voltage between LATCH ENABLE
and /LATCH ENABLE as shown in Figure X.X. Hysteresis
generated in this manner is independent of output swing and is
symmetrical around zero. The variation of hysteresis with input
voltage is shown in Figure 5.
V REF ± VOS
DISPERSION
Q OUTPUT
Figure 4
COMPARATOR HYSTERESIS TRANSFER
FUNCTION USING LATCH ENABLE INPUT
COMPARATOR HYSTERESIS
HYSTERESIS - mV
The addition of hysteresis to a comparator is often useful in a
noisy environment or where it is not desirable for the
comparator to toggle between states when the input signal is at
the switching threshold. The transfer function for a comparator
with hysteresis is shown in Figure 4 below. If the input voltage
approaches the threshold from the negative direction, the
comparator will switch from a “0” to a “1” when the input
crosses +VH/2. The “new” switching threshold now becomes –
VH/2. The comparator will remain in a “1” state until the
threshold –VH/2 is crossed coming from the positive direction.
In this manner, noise centered around 0 V input will not cause
the comparator to switch states unless it exceeds the region
bounded by ±VH/2.
0
-30
Figure 6
Positive feedback from the output to the input is often used to
produce hysteresis in a comparator.
THERMAL CONSIDERATIONS
COMPARATOR HYSTERESIS TRANSFER FUNCTION
-VH
2
0V
The AD53519 PLCC package option has a theta JA (junction to
ambient thermal resistance) of 89.4 °C /W in still air.
+VH
2
INPUT
Upgrading the SPT9689 and AD96687
“1"
The AD53519 dual comparator is pin-for-pin compatible with
the SPT9689 and AD96687 and offers many improvements over
these devices. The most notable difference is in propagation
delay. The SPT9689 and AD96687 can be easily replaced with
the higher performance AD53519, but there are differences and
it is useful to check that these ensure proper operation.
The major differences between the SPT9689 and AD53519
include Propagation Delay, Latch to Output Delay, Bandwidth,
Rise Time, Fall Time, Input Offset Voltage (SPT9689B) and
Offset Voltage Tempco (SPT9689B).
“0"
OUTPUT
Figure 5
REV. Pr J July 22, 2002
0
-20
-10
10
20
30
DIFFERENTIAL LATCH VOLTAGE - mV
- 8 -
PRELIMINARY TECHNICAL DATA
AD53519
TYPCIAL APPLICATION CIRCUITS
HIGH SPEED SAMPLING CIRCUIT
AD53519
+
VIN
OUTPUTS
VREF
-
ALL RESISTORS 50 OHM
UNLESS OTHERWISE
NOTED
LATCH
ENABLE
INPUTS
-2.0 V
Figure 7
HIGH SPEED WINDOW COMPARATOR
AD53519
+VREF
+
OUTPUTS
VIN
-
AD53519
+
-VREF
-
LATCH
-2.0 V
ENABLE
INPUTS
ALL RESISTORS 50 OHM UNLESS OTHERWISE NOTED
REV. Pr J July 22, 2002
- 9 -
Figure 8
PRELIMINARY TECHNICAL DATA
AD53519
HYSTERESIS USING POSITIVE FEEDBACK
AD53519
+
VIN
OUTPUTS
VREF
R1
R2
-2.0 V
Figure 9
HYSTERESIS USING LATCH ENABLE INPUT
AD53519
VIN
+
OUTPUTS
-
HYSTERESIS
VOLTAGE
450
-2.0 V
ALL RESISTORS 50 OHM
UNLESS OTHERWISE
NOTED
Figure 10
REV. Pr J July 22, 2002
- 10 -
PRELIMINARY TECHNICAL DATA
AD53519
HOW TO INTERFACE AN ECL OUTPUT TO AN INSTRUMENT WITH A 50 OHM
TO GROUND INPUT
AD53519
+
VIN
127
30
50
30
50
127
-5.2 V
Figure 11
ESD PROTECTION CIRCUITS
All input and output pins contain ADI Proprietary ESD
protection diodes.
ESD WARNING!!! ESD (Electrostatic
discharge) sensitive device. Electrostatic
charges as high as 4000 V readily accumulate
on the human body and test equipment and
can discharge without detection. Although
the AD53519 features proprietary ESD
protection circuitry, permanent damage may
occur on devices subjected to high energy
electrostatic discharges. Therefore, proper
ESD precautions are recommended to avoid
performance degradation or loss of
functionality.
VCC
EQUIVALENT ESD
PROTECTION CIRCUIT
INPUT
VEE
Figure 12
TYPICAL PERFORMANCE CHARACTERISTICS (VCC = +5.0V, VEE = -5.20V, TA = +25°C UNLESS OTHERWISE
NOTED)
Title
0
0
0
0
0
0
0
Title
0
0
0
POSSIBLE CHARTS TO BE ADDED.
REV. Pr J July 22, 2002
- 11 -
PRELIMINARY TECHNICAL DATA
AD53519
•
Propagation Delay vs. Overdrive Voltage
•
Propagation Delay vs. Temperature
•
Propagation Delay vs. Common Mode Voltage
•
Rise Time vs. Temperature
•
Hysteresis vs. ∆Latch
•
Rise and Fall of Outputs vs. Time Crossover
•
Fall Time vs. Temperature
•
Input Bias Current vs. Common Mode Voltage
•
Input Bias Current vs. Input Voltage
•
Input Bias Current vs. Temperature
•
Input Offset Voltage vs. Temperature
REV. Pr J July 22, 2002
- 12 -
PRELIMINARY TECHNICAL DATA
AD53519
Mechanical Outline Dimensions
Dimensions shown in inches and (mm).
20-Pin PLCC
0.048
(1.21)
0.042
0.048 (1.21)(1.07)
0.042 (1.07)
3
PIN 1
IDENTIFIE
R
4
18
TOP VIEW
(PINS DOWN)
REV. Pr J July 22, 2002
9
13
0.356 (9.04)
0.350 (8.89) SQ
0.395
(10.02) SQ
0.385 (9.78)
0.025 (0.63)
0.015 (0.38)
0.021
(0.53)
0.013
(0.33)0.032
(0.81)
0.026
(0.66)
0.040 (1.01)
0.025 (0.64)
0.050
(1.27)
BSC
14
8
0.020
(0.50
)
R
0.180
(4.57)
0.165
(4.19)
0.056
(1.42)
0.042
19
(1.07)
0.110
(2.79)
0.085
(2.16)
- 13 -
0.020 (0.50)
R
0.330
(8.38)
0.290
(7.37)
PIN 1
IDENTIFIE
R
BOTTOM
VIEW
(PINS UP)