TI PT4711C

PT4711—48V
45-W Dual-Output Isolated
DC/DC Converter
SLTS225 APRIL 2004
Features
• Input Voltage: 36 V to 75 V
• Dual Output (15 V / 15 V)
(Independently Regulated!)
• Separate Output Returns
(Accommodates ±15 V or +30 V)
• Internal Power-Up Sequencing
• Flexible On/Off Control
• Output Current Limit
• Fixed Frequency Operation
Description
•
•
•
•
Over-Temperature Shutdown
Under-Voltage Lockout
1500 VDC Isolation
Space-Saving Solderable Case
1.2 sq. in. PCB Area (suffix N)
• Surface Mount Option
• Safety Approvals (Pending):
UL 60950, cUL 60950
Ordering Information
The PT4711 Excalibur™ power
module is a 45-watt rated DC/DC
converter that produces two regulated output supply voltages from a
standard (–48 V) telecom central
office supply.
Both of the outputs from this
module are truly independent. Each
is separately regulated and has its
own negative return. This allows the
flexibility of configuring the output
for up to three voltage options. This
includes a complimentary dual ±15-V,
or a single +30-V or –30-V output.
PT4711❏
❏ = 15 V / 15 V
The PT4711 incorporates many
features to simplify system integration. These include a flexible On/Off
enable control, input under-voltage
lock-out, and over-temperature protection. All outputs are short-circuit
protected, and internally sequenced
for simultaneous power-up and powerdown.
The module is packaged in a
space-saving solderable copper case,
requires no heat sink, and can occupy
as little as 1.2 in2 of PCB area.
PT Series Suffix (PT1234 x )
Case/Pin
Configuration
Vertical
Horizontal
SMD
Order
Suffix
Package
Code
N
A
C
(ENM)
(ENN)
(ENP)
(Reference the applicable package code drawing for
the dimensions and PC layout)
Typical Application
PT4711
+Vo1
1
+VIN
+VIN
V1 Adj
14
+15 V
17
+
Co1
–Vo1 16
+
CIN
3
4
–VIN
2
EN 2
EN 1
–VIN
+Vo2
18
+
V2 Adj
–Vo2
21
20
Co2
–15 V
Co 1, Co 2:
Cin:
EN1 & EN2 pins:
For technical support and further information, visit http://power.ti.com
Recommended 150 µF
Optional 47 µF electrolytic
See On/Off Enable Logic
PT4711—48V
45-W Dual-Output Isolated
DC/DC Converter
SLTS225 APRIL 2004
Pin Configuration
On/Off Enable Logic
Pin Function
Pin Function
Pin Function
Pin 3
1
+Vin
8
Pin Not Present
15
Not Connected
2
–Vin
9
Pin Not Present
16
–Vo1
3
EN 2
10
Pin Not Present
17
Vo1 Adjust
4
EN 1
11
Pin Not Present
18
+Vo2
5
Do Not Connect
12
Pin Not Present
19
Not Connected
6
Do Not Connect
13
Pin Not Present
20
–Vo2
7
Do Not Connect
14
+Vo1
21
Vo2 Adjust
Note: Shaded functions indicates those pins that are at primary-side
potential. All other pins are referenced to the secondary.
Pin 4
Output Status
×
1
Off
1
0
On
0
×
Off
Notes:
Logic 1 =Open collector
Logic 0 = –Vin (pin 2) potential
For positive Enable function, connect pin 4
to pin 2 and use pin 3.
For negative Enable function, leave pin 3
open and use pin 4.
Pin Descriptions
+Vin: The positive input supply for the module with
respect to –Vin. When powering the module from a
–48-V telecom central office supply, this input is
connected to the primary system ground.
–Vo 1: The negative output supply voltage with
respect to +Vo1 . If this node is connected to the
secondary ground, a positive voltage is produced at
+Vo1.
–Vin: The negative input supply for the module, and
the 0-VDC reference for the EN 1, and EN 2 inputs.
When powering the module from a +48-V supply,
this input is connected to the input source return.
+Vo 2: This is the positive DC output voltage with
respect to –Vo2. The output voltage produced across
±Vo2 is electrically isolated from ±Vin and independently regulated from that produced at ±Vo1. If +Vo2
node is connected to the secondary ground, a negative output voltage will be produced at –Vo2.
EN 1: The negative logic input that activates the
module output. This pin must be connected to –Vin
to enable the module’s outputs. A high impedance
disables the module’s outputs.
EN 2: The positive logic input that activates the
module output. If not used, this pin should be left
open circuit. Connecting this input to –Vin disables
the module’s outputs.
+Vo 1: This is the positive DC output voltage with
respect to –Vo1. The output voltage produced across
±Vo1 is electrically isolated from ±Vin and independently regulated from that produced at ±Vo2. If the
+Vo1 node is connected to the secondary ground, a
negative output voltage will be produced at –Vo1.
–Vo 2: The negative output supply voltage with
respect to +Vo2 . If this node is connected to the
secondary ground, a positive voltage is produced
at +Vo2.
±Vo1 Adjust: Using a single resistor, this pin allows
the output voltage produced at ±Vo1 to be adjusted
higher or lower by up to 10%. If not used this pin
should be left open circuit.
±Vo2 Adjust: Using a single resistor, this pin allows
the output voltage produced at ±Vo2 to be adjusted
higher or lower by up to 10%. If not used this pin
should be left open circuit.
For technical support and further information, visit http://power.ti.com
PT4711—48V
45-W Dual-Output Isolated
DC/DC Converter
SLTS225 APRIL 2004
PT4711 Electrical Specifications
(Unless otherwise stated, the operating conditions are:- Ta =25°C, V in =48 V, and I o =Io max)
Characteristics
Symbols
Conditions
Min
PT4711
Typ
Max
Units
Output Current
Input Voltage Range
Io1, Io2
Vin
Both outputs
Continuous
Surge (1 minute)
Vo1, Vo2
∆Regtemp
∆Regline
∆Regload
∆Regcross
—
—
—
15.0
±0.5
±0.05
±0.2
1.5
75
80
15.45
—
±0.25
±0.5
A
Set-Point Voltage
Temperature Variation
Line Regulation
Load Regulation
Cross Regulation
0
36
—
14.55
—
—
—
—
±10
—
mV
Total Output Voltage Variation
∆Vo tot
14.25
—
15.75
V
Efficiency
Vo Ripple (pk-pk)
η
Vn
—
Transient Response
Output Adjust Range
Current Limit Threshold
Switching Frequency
Under Voltage Lockout
–40°C ≤Ta ≤+85°C, Io =Iomin
All outputs, Over Vin range
All outputs, 0≤Io≤Iomax
Io1 =Io1max, 0 ≤ Io2 ≤ Io2max
Io2 =Io2max, 0 ≤ Io1 ≤ Io1max
Includes set-point, line, load,
–40°C ≤Ta ≤+85°C
Vo1, Vo2
Vo1 , Vo2
V
V
%Vo
%Vo
%Vo
86
—
%
—
15
—
mVpp
ttr
Vos
Vox adj
IoLIM
ƒs
Measured from each output to COM, Vo , Vo
1
2
0 to 20 MHz bandwidth
0.1 A/µs load step, 50% to 75% Iomax
Vo over/undershoot
Each Vo adjusted independently
Shutdown, auto restart
Vo1, Vo2
Over Vin and Io ranges
—
—
—
—
550
100
2
±10
2.5
600
—
—
—
—
650
µSec
%Vo
%Vo
A
kHz
Von
Voff
Vin increasing
Vin decreasing
—
—
34
32
—
—
V
4
–0.2
—
—
Open
0.8
Enable Control (pins 3 & 4)
High-Level Input Voltage
Low-Level Input Voltage
Low-Level Input Current
VIH
VIL
IIL
Pin connected to –Vin (pin 2)
—
–0.16
—
mA
Standby Input Current
Iin standby
pins 3 & 4 open circuit
—
5
20
mA
Internal Input Capacitance
Cint
—
1
—
µF
External Output Capacitance
Primary/Secondary Isolation
Co
V iso
C iso
R iso
∆Vsec
Ta
Treflow
Ts
0
1500
—
10
—
–40
—
–40
—
—
2,200
—
—
—
—
—
500
—
—
—
35
85
215
125
µF
V
pF
MΩ
V
°C
°C
°C
—
500
—
G’s
—
—
—
15 (5)
20 (5)
50
115
—
—
—
125
G’s
Secondary Working Voltage
Operating Temperature Range
Solder Reflow Temperature
Storage Temperature
Mechanical Shock
Referenced to –Vin (pin 2)
Mechanical Vibration
Weight
ShutdownTemperature
Flammability
—
OTP
—
Each output to COM
Vo1, Vo2
Between any two output pins
Over Vin Range
Surface temperature of module pins or case
—
Per Mil-STD-883D, Method 2002.3
1 msec, ½ Sine, mounted
Mil-STD-883D, Method 2007.2
Suffix A
20-2000 Hz
Suffix N, C
Vertical/Horizontal
(1)
(1)
(2)
(3)
(4)
V
grams
°C
Meets UL 94V-O
Notes: (1) The Enable inputs (pins 3 & 4) have internal pull-ups. Leaving pin 3 open-circuit and connecting pin 4 to –V in allows the the converter to operate when
input power is applied. The maximum open-circuit voltage is 5 V.
(2) The maximum voltage that may exist between any two output pins.
(3) See SOA curves or consult factory for appropriate derating.
(4) During solder reflow of SMD package version, do not elevate the module case, pins, or internal component temperatures above a peak of 215°C. For
further guidance refer to the application note, “Reflow Soldering Requirements for Plug-in Power Surface Mount Products,” (SLTA051).
(5) Only the case pins on through-hole pin configurations (N & A) must be soldered. For more information see the applicable package outline drawing.
For technical support and further information, visit http://power.ti.com
Typical Characteristics
PT4711—48V
45-W Dual-Output Isolated
DC/DC Converter
SLTS225 APRIL 2004
Performance Characteristics; Vin =48 V (See Note A)
PT4711 Safe Operating Area (SOA)
(Refer to typical application for output configuration)
(All outputs proportionally loaded from 0 to 100 % of full load)
(See Note B)
SOA vs Total Output Power; V in =48 V
Efficiency vs Io1 & |Io2|
90
90
Efficiency - %
VIN
36 V
48 V
75 V
70
60
Ambient Temperature (°C)
80
80
Airflow
70
300LFM
200LFM
100LFM
Nat conv
60
50
40
30
50
20
0
0.3
0.6
0.9
1.2
1.5
0
Io1 & |Io2| (A)
10
20
30
40
Output Power (W)
Power Dissipation vs Io1 & |Io2|
10
Pd - Watts
8
6
75 V
48 V
36 V
4
2
0
0
0.3
0.6
0.9
1.2
1.5
Io1 & |Io2| (A)
Cross Regulation; Vo1 vs |Io 2|
Cross Regulation Vo1 (V)
15.02
15.01
15.00
14.99
14.98
0
0.3
0.6
0.9
1.2
1.5
1.2
1.5
|Io2| (A)
Cross Regulation |Vo2| vs Io1
Cross Regulation |Vo2| (V)
15.02
15.01
15.00
14.99
14.98
0
0.3
0.6
0.9
Io1 (A)
Note A: All Characteristic data in the above graphs has been developed from actual products tested at 25°C. This data is considered typical data for the ISR.
Note B: SOA curves represent operating conditions at which the internal components are at or below the manufacturer’s maximum rated operating temperatures.
For technical support and further information, visit http://power.ti.com
Application Notes
PT4711
Operating Features of the PT4711
Dual-Output DC/DC Converter
Over-Current Protection
Each of the two outputs from the PT4711 DC/DC converter incorporates protection against an output load
fault. When a fault impedance is applied to one output,
the module initially limits the output current of that
output to approximately 150% of the maximum current
rating. If the fault persists for more than 20 ms the converter shuts down, forcing the voltage at both regulated
outputs to simultaneously fall to zero. Following shutdown
the converter periodically attempts to recover by executing
a soft-start power-up. The converter will contine in a cycle
of successive shutdowns and restarts until the load fault
is removed.
Over-Temperature Protection
The PT4711 DC/DC converter has an internal temperature sensor, which monitors the temperature of the
module’s internal components. If the sensed temperature
exceeds a nominal 115°C, the converter will shut down.
The converter will automatically restart when the sensed
temperature returns to about 100°C.
Under-Voltage Lock-Out
Input Current Limiting
The converter is not internally fused. For safety and
overall system protection, the maximum input current to
the converter must be limited. Active or passive current
limiting can be used. Passive current limiting can be a
fast acting fuse. A 125-V fuse, rated no more than 5 A, is
recommended. Active current limiting can be implemented with a current limited “Hot-Swap” controller.
Output Voltage Configurations
Both outputs from the PT4711 DC/DC converter are
independently regulated and isolated from each other.
This allows flexibility to how the output voltages may
be configured (up to the maximum allowed working
voltage between the two outputs; see specification table).
Figure 1-1 shows the most common ways that the outputs
of the converter may be configured. They include ±Vo
(Fig. 1-1a), Vo(a)/Vo(b) (Fig. 1-1b), and 2 × Vo (Fig. 1-1c).
Figure 1-1; PT4711 Output Voltage Configurations
+Vo1
DC/DC
Module
–Vo1
The Under-Voltage Lock-Out (UVLO) circuit prevents
operation of the converter whenever the input voltage to
the module is insufficient to maintain output regulation.
The UVLO has approximately 2 V of hysterisis. This is
to prevent oscillation with a slowly changing input voltage. Below the UVLO threshold the module is off and
the enable control inputs, EN1 and EN2 are inoperative.
Primary-Secondary Isolation
The PT4711 DC/DC converter incorporates electrical
isolation between the input terminals (primary) and the
output terminals (secondary). All converters are production
tested to a withstand voltage of 1500 VDC. The isolation
complies with UL/cUL 60950 and EN60950, and the
requirements for operational isolation. This allows the
converter to be configured for either a positive or negative input voltage source.
The regulation control circuitry for these modules is
located on the secondary (output) side of the isolation
barrier. Control signals are passed between the primary
and secondary sides of the converter. The data sheet ‘Pin
Descriptions’ and ‘Pin-Out Information’ provides guidance as to which reference (primary or secondary) that
must be used for each of the external control pin.
+Vo2
–Vo2
14
+Vo
16
18
20
–Vo
a. ±Vo Center Common
+Vo1
14
+Vo(a)
DC/DC
Module –Vo 16
1
+Vo2
–Vo2
18
+Vo(b)
20
b. +Vo(a)/+Vo(b)
+Vo1
DC/DC
Module
–Vo1
+Vo2
–Vo2
14
2 × Vo
16
18
20
c. 2 × +Vo
For technical support and further information, visit http://power.ti.com
Application Notes
PT4711
Using the On/Off Enable Controls on the PT4711
Dual-Output DC/DC Converter
The PT4711 is a dual-output DC/DC converter incorporates two output enable controls. EN1 (pin 4) is the
Negative Enable input, and EN2 (pin 3) is the Positive
Enable input. Both inputs are electrically referenced to
-Vin (pin 2) on the primary or input side of the converter.
A pull-up resistor is not required, but may be added if
desired. Voltages of up to 70 V can be safely applied to
the either of the Enable pins.
pin 4 in order to enable the outputs of the converter.
An example of this configuration is detailed in Figure 2.
Note: The converter will only produce an output voltage if a
valid input voltage is applied to ±Vin.
Figure 2; Negative Enable Configuration
DC/DC
Module
Automatic (UVLO) Power-Up
3
Connecting EN1 (pin 4) to -Vin (pin 2) and leaving EN2
(pin 3) open-circuit configures the converter for automatic power up. (See data sheet “Typical Application”).
The converter control circuitry incorporates an “Under
Voltage Lockout” (UVLO) function, which disables the
converter until the minimum specified input voltage is
present at ±Vin. (See data sheet Specifications). The UVLO
circuitry ensures a clean transition during power-up and
power-down, allowing the converter to tolerate a slowrising input voltage. For most applications EN1 and EN2,
can be configured for automatic power-up.
Positive Output Enable (Negative Inhibit)
To configure the converter for a positive enable function,
connect EN1 (pin 4) to -Vin (pin 2), and apply the system
On/Off control signal to EN2 (pin 3). In this configuration, a low-level input voltage (-Vin potential) applied to
pin 3 disables the converter outputs. Figure 1 is an example
of this configuration.
4
EN 2
EN 1*
BSS138
1 =Outputs On
–VIN
2
–Vin
On/Off Output Voltage Sequencing
Both outputs from the PT4711 converter are internally
sequenced to power up in unison. Figure 3-3 shows the
output waveforms after the module’s output has been
enabled. The converter produces a fully regulated output
within 75 ms. The waveforms were measured with the
output voltages configured per Figure 1-1a (for ±15-V
output). A constant current load of 1.5 A was applied to
both outputs, with an input source of 48 VDC.
Figure 3-3; PT4711 Power-up Sequence
Figure 1; Positive Enable Configuration
+Vo1 (5 V/Div)
DC/DC
Module
3
4
BSS138
EN 2
EN 1*
1 =Outputs Off
–VIN
2
–Vin
+Vo2 (5 V/Div)
Negative Output Enable (Positive Inhibit)
HORIZ SCALE: 5 ms/Div
To configure the converter for a negative enable function,
EN2 (pin 3) is left open circuit, and the system On/Off
control signal is applied to EN1 (pin 4). A low-level
input voltage (-Vin potential) must then be applied to
For technical support and further information, visit http://power.ti.com
Application Notes
PT4711
Adjusting the Output Voltages of the PT4711
Dual-Output DC/DC Converters
The PT4711 dual-output DC/DC converter produces
two independently regulated output voltages. The magnitude of each output may be trimmed higher or lower
than the nominal set-point by up to 10%. The adjustment method uses a single external resistor. 1 The value
of the resistor determines the magnitude of adjustment,
and the location of the resistor determines the direction
of adjustment (increase or decrease). The resistor values
can be calculated using a formula (see below). Alternatively the resistor value may be selected directly from
the values given in Table 2-2. The placement of each
resistor is as follows.
Adjust Down: To decrease the magnitude of the output
voltage, add a resistor (R2), between the appropriate Vox
Adj (Vo1 Adj or Vo2 Adj,) and the respective +Vox voltage
rail. See Figure 2-1(b) and Table 2-1 for the resistor
placement and pin connections.
Adjust Up: To increase the magnitude of the output voltage, add a resistor R1 between the appropriate Vo x Adj
(‘Vo1 Adj’ or ‘Vo2 Adj’) and the respective -Vo x voltage
rail. See Figure 2-1(a) and Table 2-1 for the resistor
placement and pin connections.
(R2)
Figure 2-1b
DC/DC
Module
#
+Vox
+Vox
To adjust the Vo1
or Vo2 lower
#
Vox Adj
#
–Vox
–Vo x
# - See Table 3-1 for pin connections,
where Vox indicates Vo1, or Vo 2
Figure 2-1a
DC/DC
Module
Table 2-1; Adjust Resistor Pin Connections
+Vox
Vox Adj
#
+Vox
To adjust the Vo1
or Vo2 higher
#
R1
–Vox
#
To Adjust Up
Connect R1
from
to
–Vo x
# - See Table 3-1 for pin connections,
where Vox indicates Vo1, or Vo 2
Vox Adj
To Adjust Down
Connect (R2)
from
to
Vox Adj
+Vox
Vo1
17
–Vox
16
17
14
Vo2
21
20
21
18
Calculation of Resistor Adjust Values
The adjust resistor value may also be calculated using an
equation. Note that the equation for R1 [Adjust Up] is
different to that for (R2) [Adjust Down].
Notes:
1. Use only a single 1% (or better) tolerance resistor in
either the R1 or (R2) location to adjust a specific output.
Place the resistor as close to the ISR as possible.
2. Never connect capacitors to any of the ‘Vox Adj’ pins. Any
capacitance added to these control pins will affect the
stability of the respective regulated output.
For technical support and further information, visit http://power.ti.com
R1 [Adjust Up]
=
35.75
(Va – Vo )
(R2) [Adjust Down]
=
14.3 (Va – 2.5)
– 20 kΩ
(Vo – Va )
– 20
Where: Vo = Original output voltage (Vox)
Va = Adjusted output voltage (Vax)
kΩ
Application Notes continued
PT4711
Table 2-2
ADJUSTMENT RESISTOR VALUES FOR Vo1 & Vo2
Adj. Resistor
% Adjust
–10%
– 9%
– 8%
– 7%
– 6%
– 5%
– 4%
– 3%
– 2%
– 1%
0%
+ 1%
+ 2%
+ 3%
+ 4%
+ 5%
+ 6%
+ 7%
+ 8%
+ 9%
+10%
R1 = Black, R2
R1/(R 2)
Va (req’d)
13.50 V
13.65 V
13.80 V
13.95 V
14.10 V
14.25 V
14.40 V
14.55 V
14.70 V
14.85 V
15.00 V
15.15 V
15.30 V
15.45 V
15.60 V
15.75 V
15.90 V
16.05 V
16.20 V
16.35 V
16.50 V
= (Blue)
(84.9) kΩ
(98.1) kΩ
(115) kΩ
(136) kΩ
(164) kΩ
(204) kΩ
(264) kΩ
(363) kΩ
(562) kΩ
(1.16) MΩ
218 kΩ
99.2 kΩ
59.4 kΩ
39.6 kΩ
27.7 kΩ
19.7 kΩ
14.0 kΩ
9.8 kΩ
6.5 kΩ
3.8 kΩ
For technical support and further information, visit http://power.ti.com
PACKAGE OPTION ADDENDUM
www.ti.com
6-Dec-2006
PACKAGING INFORMATION
Orderable Device
Status (1)
Package
Type
Package
Drawing
Pins Package Eco Plan (2)
Qty
PT4711A
ACTIVE
SIP MOD
ULE
ENN
21
8
TBD
Call TI
Level-1-215C-UNLIM
PT4711C
ACTIVE
SIP MOD
ULE
ENP
21
8
TBD
Call TI
Level-3-215C-168HRS
PT4711N
ACTIVE
SIP MOD
ULE
ENM
21
8
TBD
Call TI
Level-1-215C-UNLIM
Lead/Ball Finish
MSL Peak Temp (3)
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in
a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check
http://www.ti.com/productcontent for the latest availability information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements
for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered
at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and
package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS
compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame
retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder
temperature.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is
provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the
accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and continues to take
reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on
incoming materials and chemicals. TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited
information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI
to Customer on an annual basis.
Addendum-Page 1
MMSI070A - OCTOBER 2001 - REVISED - FEBRUARY 2003
MECHANICAL DATA
MMSI071 – OCTOBER 2001
ENN (R–MSIP–T21)
METAL SINGLE–IN-LINE MODULE
Suffix A
1.62 (41,14) MAX
1.46 (37,08) MAX
2.58 (65,53) MAX.
Note G
0.472 (12,00) MAX
1
0.025 (0,63) TYP.
0.017 (0,43) TYP.
0.100 (2,54) TYP.
0.160 (4,06) TYP.
0.032 (0,81) TYP.
0.140 (3,55) MIN.
See Note F
0.040 (1,01) TYP.
2.620 (66,54)
0.040 (1,01)
0.080 (2,03)
2.520 (64,00)
0.51
(12,95)
0.250
(6,35)
1.500 (38,10)
0.050 (1,27)
Note H
0.160 (4,06)
1.260 1.44
(32,00) (36,57)
Note E
4 Places
0.110 (2,79)
1
Note E
∅0.045 (1,14) MIN. 21 Places
Plated through, Note J
0.100 (2,54) 20 Places
∅0.065 (1,65) MIN. 4 Places
Plated through holes.
See note G.
0.280 (7,11)
0.080 (2,03)
2 Places
0.260 (6,60)
PC LAYOUT
NOTES: A.
B.
C.
D.
E.
F.
G.
H.
J.
All linear dimensions are in inches (mm).
This drawing is subject to change without notice.
2 place decimals are ±0.030 (±0,76mm).
3 place decimals are ±0.010 (±0,25mm).
Recommended mechanical keep out area.
Electrical pin length mounted on printed circuit board, from seating plane to pin end.
The case is electrically uncommitted. The recommended connection is to secondary ground.
No copper, power or signal traces in this area.
Some pins may not be present, see product specifications.
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
4203487/A 10/01
MECHANICAL DATA
MMSI072 – OCTOBER 2001
ENP (R–MSIP–G21)
METAL SINGLE–IN-LINE MODULE
Suffix C
1.62 (41,14) MAX
1.46 (37,08) MAX
2.58 (65,53) MAX.
0.472 (12,00) MAX
1
0.025 (0,63) TYP.
0.100 (2,54) TYP.
0.160 (4,06) TYP.
Detail ”A”
0.032 (0,81) TYP.
0.040 (1,01) TYP.
2.620 (66,54)
2.520 (64,00)
0.040 (1,01)
0.230 (5,84)
0.210 (5,33)
Note E
0.51
(12,95)
1.500 (38,10)
0.250
(6,35)
Note J
1.260 1.44
(32,00) (36,57)
Note I
1
0.050 (1,27)
0.165 (4,19)
Note E
2 Places
∅0.065 (1,65) MIN. 4 Places
Plated through holes.
See note H.
0.090 (2,28)
0.070 (1,77)
Note F
Note G, H
NOTES: A.
B.
C.
D.
E.
F.
G.
0.050 (1,27)
0.280 (7,11)
0.050 (1,27) 21 Places
Note K
0.100 (2,54) 20 Places
0.080 (2,03)
2 Places
0.260 (6,60)
PC LAYOUT
0.100 (2,54)
0.050 (1,27)
0.017 (0,43) TYP.
Gage Plane
0.140
(3,55)
Seating Plane
0.004 (0,10)
0°– 60°
0.080 (2,03)
0.100 (2,54)
All linear dimensions are in inches (mm).
This drawing is subject to change without notice.
2 place decimals are ±0.030 (±0,76mm).
3 place decimals are ±0.010 (±0,25mm).
Recommended mechanical keep out area.
Vias are recommended to improve copper adhesion.
Solder mask openings to copper island for solder joints
to mechanical pins.
POST OFFICE BOX 655303
Detail ”A”
4203488/A 10/01
H. The case is electrically uncommitted. The
recommended connection is to secondary ground.
I. Power pin connections should utilize two or more vias
per input, ground and output pin.
J. No copper, power or signal traces in this area.
K. Some pins may not be present, see product
specifications.
• DALLAS, TEXAS 75265
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