HRS EX40T

NEW
High-Speed Differential Signal Connectors
EXT Series
1 Gbps Eye Pattern Waveform
(One End of Connector: 2 m of AWG #28 Twinax Cable)
The construction supports high-speed differential signals
such as LVDS, IEEE 1394, and USB 2.0. Use of twisted pair
cable or twinax cable permits transmission speeds up to
several hundred Mbps and higher per twisted pair.
(A) Impedance Matching
The connector is designed to minimize reflections with a
differential impedance of 100 ohms between adjacent contacts.
(B) Low Skew Construction
An equivalent electrical length is maintained between
adjacent contacts while the equivalent electrical length
between opposing terminals is approximately zero.
Consequently the skew within differential pairs as well as
between differential pairs is approximately zero.
However, a low skew between differential pairs is permitted
by going through another layer of the board.
(C) Low Crosstalk
The design features a staggered arrangement between
opposing contacts for low crosstalk effects between opposing
pairs even though these are low-profile connectors.
Gap between opposing contacts
01. High-Speed Differential Signals
Adjacent contacts
Equivalent electrical length
■Features
Differential impedance
between adjacent
contacts is 100 ohms
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02. Batch Wiring of Cables Using Solder Paste
Soldered wiring has been used as the wiring method for the
plug side composite cable, thin cable, and drain wires;
however, paste soldering permits the batch wiring of
prepared cables. (Existing soldering methods can also be
used to wire the connectors.)
03. No Shrink Tubing Required
The wiring portion of the plug side is secured by the
molding which prevents short circuits without the use of
shrink tubing. Since shrink tubing is not used, this
allows the twist back length of the twisted pair cable or
the twinax cable to be shortened, thereby permitting the
impedance of the wiring section to be kept in check.
04. Power and Signal Contacts
The 65 position connector is designed with 59 signal contacts and 6 power contacts. Each power contact is
rated for 2 Amps. The 71 position connector is supplied with signal contacts only.
05. Low-Profile Design
With the trend toward lower profiles, the receptacle is made to drop into the board, which results in a height
dimension, including the board, of 5.6mm.
2001.6
1
■Product Specification
Ratings
Operation temperature range
–55ç to +85ç
Voltage
125 V AC
Current
Item
1. Contact resistance
Signal contacts
1A
Power supply contacts
2A
Standard
Signal contacts: 40 mø max.
Power supply contacts: 16 mø max.
Condition
Measured at 100 mA
2. Insulation resistance 500 Mø max.
Measured at 250 V DC
3. Withstand voltage No flashover or insulation breakdown
Applied a voltage of 350 V AC for one minute.
Contact resistance
Signal contacts: 60 mø max.
4. Mechanical operation
Power supply contacts: 24 mø max.
No damage, cracks, or loose parts
Performed 3,000 cycles of insertion/withdrawal.
5. Vibration
6. Shock
No momentary disconnections of 1µs max.
Contact resistance
Signal contacts: 60 mø max.
Power supply contacts: 24 mø max.
No damage, cracks, or loose parts
7. Temperature cycle Contact resistance
Signal contacts: 60 mø max.
Power supply contacts: 24 mø max.
Insulation resistance: 500 Mø max.
8. Steady-state
8. humidity resistance No damage, cracks, or loose parts
9. Salt spray
No conspicuous corrosion
Frequency: 10 to 55 Hz (5 minutes per cycle)
Total amplitude: Test at 1.5 mm in 3 directions, 2 hours each
Acceleration: 490 m/s2, 11 ms duration
Test with a sine wave in 3 axes, both directions, 3 times
each
Conduct a test of 5 cycles of the following:
Temperature cycle: –55 ➝ +15 to +35➝ +85 ➝ +15 to +35ç
Time
: –30 ➝ +10 to +15➝ +30 ➝ 10 to 15 minutes
Temperature of 40ç ±2ç and humidity of 90% to 95%
for 96 hours
5% concentration of salt water for 48 hours
■Materials
●Receptacle
Part
Material
Finish
Contacts
Copper alloy
Insulator
LCP
Gold plating
Body
Steel
Nickel plating
Metal Fitting
Stainless steel
Solder plating
UL94U-0
●Plug
Part
Material
Finish
Contacts
Copper alloy
Selective gold plating
Insulator
LCP
UL94U-0
Body
Steel
Nickel plating
Strain relief
Polycarbonate
UL94U-0
●Cover
Part
2
Material
Finish
Cover
Polycarbonate
UL94HB
Shield
Stainless steel
-----
Lock
Stainless steel
-----
Push button
Polycarbonate
UL94HB
Clamp
Brass
-----
Metal hold down
Steel
Black nickel plating
■Ordering Information
●Receptacles
E X 6 0 T - C 71 P
1
2
1
3
4
E X 4 0 T - C 71 P R
2
1
3
4
5
Series name : EX**T
2
Wiring type : 40 : Cable soldering type
: 60 : Right angle SMT type
5
●Plugs
1
1
3
Body size
4
5
Number of conductors
Contact type : P : Male contact
: S : Female contact
6
6
Connector mating direction : No symbol : Standard type
●Case cover
: R : Reverse type
E X 4 0 T - C CT
1
2
1
3
7
Cover type
: CT : Straight type
: CV : Angled type
7
■Connector Mounting Reference Diagram
Using a standard type plug (EX40T-C71S)
EX40T-CCT
EX60T-C71P
( 4.5 )
( 5.5 )
PCB mounting surface
Cover screw surface
( 6.5 )
Cover screw surface
( 6.5 )
EX40T-CCT
Using a reverse type plug (EX40T-C71SR)
;
;
;
( 4.3 )
( 5.3 )
EX60T-C71P
( 4.5 )
( 5.5 )
;
;
;
( 4.3 )
( 5.3 )
PCB mounting surface
3
■Receptacle
●71 contact (Signal contacts only)
EX60T–C71P (CL232–0584–4)
39.2
.8
36
P= 0.5
Ø2
1.5
5
5
9.4
A
50.6
54.6
5.6
2.9
56.2
Board SMT surface
BBoard Mounting Diagram (for Reference)
Establishing the discardable portion of the board indicated by the shaded area of the diagram below, serves to prevent the
board from falling forward at the time of reflow. Making a V-shaped cut in the discardable portion of the board allows access to
the connector by bending and breaking off this portion after reflow.
Ø1.25 (Hole)
45.2
40.6
4-1.7x1.7
1.65x1.25 (Elliptical hole)
P= 0.5
Ø3 (Hole)
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44.8
50.6
55.4
57
4
13.7
0.35
8.7
20.3
5.8
5.5
7.9
2
1.5
1.3
3.1
36
■Receptacle
●65 contact (59 signal contacts, 6 power supply contacts)
EX60T-C65P (CL232-0588-5)
39.2
.8
36
P= 0.5
Ø2
1.5
5
5
9.4
A
50.6
54.6
5.6
2.9
56.2
Board SMT surface
Power supply contacts (six)
BBoard Mounting Diagram (for Reference)
Establishing the discardable portion of the board indicated by the shaded area of the diagram below, serves to prevent the
board from falling forward at the time of reflow. Making a V-shaped cut in the discardable portion of the board allows access to
the connector by bending and breaking off this portion after reflow.
Ø1.25 (Hole)
45.2
40.6
4-1.7x1.7
1.65x1.25 (Elliptical hole)
P= 0.5
Ø3 (Hole)
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8.7
0.35
13.7
20.3
5.8
5.5
7.9
2
1.5
1.3
3.1
36
44.8
50.6
55.4
57
5
■Plug (Standard type)
●71 contact (Signal contacts only)
EX40T-C71S (CL232-0583-1)
35
5.6
4
9.2
14
P= 1
40.5
4.1
43
5.6
43.8
●65 contact (59 signal contacts, 6 power supply contacts)
EX40T-C65S (CL232-0589-8)
35
5.6
4
9.2
14
P= 1
40.5
4.1
43
5.6
43.8
Power supply contacts
6
■Plug (Reverse type)
●71 contact (Signal contacts only)
EX40T-C71SR (CL232-0587-2)
35
5.6
4
9.2
14
P= 1
40.5
4.1
43
5.6
43.8
●65 contact (59 signal contacts, 6 power supply contacts)
EX40T-C65SR (CL232-0594-8)
17
17.5
P=1
5.6
4
9.2
14
P=2
40.5
4.1
43
5.6
43.8
Power supply contacts
7
■Cover
●Straight cover
EX40T-CCT (CL232-0586-0)
8.2
8.2
10.8
39
42
5
52
8.8
●Angled cover
EX40T-CCV (CL232-0591-0)
11.4
6
47
42
5
52
8
8.8
■Technical Notes 1
●Eye Pattern Waveforms
These eye pattern waveforms are from connectors harnessed with 2 m of twinax cable for high-speed
differential signal applications.
Input Waveform
Output Waveform
●Impedance Characteristics
Impedance (ø)
These differential impedance characteristics have been measured with 45 ps rise time pulses.
The impedance drops slightly in the vicinity of the connector coupling portion.
200
180
160
140
120
100
80
60
40
20
0
Upper contacts
Lower contacts
0
100 200 300 400 500 600 700 800
Time (ps)
●Crosstalk Characteristics
Crosstalk (dB)
Crosstalk characteristics between opposing differential pairs.
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
0
100
200
300
400
500
Frequency (MHz)
9
■Technical Notes 2
●Connection Pattern of Differential Signals
Differential signals should be arranged between adjacent contacts as illustrated in the diagram below for the
purpose of impedance matching and equivalent electrical length. Furthermore, the establishment of a ground will be
effective in reducing the crosstalk between adjacent differential pairs.
Note also that for faster high-speed differential signals, gathering them to the center portion will permit control of the
electrical length at the time of harnessing.
GND
DATA2
GND
DATA2
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DATA1
DATA1
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●Low Skew Between Opposing Differential Pairs
The electrical length between adjacent contacts is equal, but the electrical length between opposing contacts differs
by approximately 1.2 mm.
As illustrated in the diagram to the right, the differential pair of contacts having a short electrical length on the upper
side of the board can be given an electrical length equivalent to that between the opposing differential pair by
adjusting the electrical length using such methods as through holes in the board.
The crosstalk on the board between differential pairs is also reduced.
Differential pair (2)
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Differential pair (1)
Upper-side contact
Electrical length adjustment portion
1.2
Lower-side contact
Difference between contact electrical lengths
●Power Supply Contacts Configuration Diagram
The 65-contact type is configured with 6 power supply contacts.
The power supply contacts are divided into 2 leads within the receptacle-side connector (EX60T-C65P) which
results in differing numbers of coupling surface-side contacts and board-side lead portion contacts.
EX60T-C71P
EX60T-C65P
Power supply contacts (6)
10
●Anchoring to the Case
Mounting of the receptacle connectors makes use of screws to fasten the connectors to the case as illustrated in the
diagram below. This contributes to a structure that is resistant to twisting.
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Embedded nut
Case
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5.6
2.9
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EX60T-71P
M2 countersunk screw
PCB
●A Design that Doesn't Use Heat-Shrink Tubing
The soldered wiring portion of the plug connector is secured to the molding which serves as a measure against the
short-circuiting of adjacent contacts. This eliminates the need to attach heat-shrink tubing.
The plug connector has been furnished with a retaining plate made of resin material for the purpose of preventing
short circuits with the metal portions of the cover case.
Insulating retaining plate
Molding
Contact
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●Batch Wiring of Plug Connectors
These connectors permit the batch soldered wiring of cables prepared with paste solder and partial reflow.
(Regularly soldered wiring is used for power supply contacts.)
Please contact our Technical Department about harness details for the purpose of satisfying harness qualities and
high-speed transmission characteristics.
11
12
ks to World El
e
Lin
onics
ctr
Creativ
e
MEMO :
HIROSE ELECTRIC CO.,LTD.
5-23,OSAKI 5-CHOME,SHINAGAWA-WARD,TOKYO 141-8587,JAPAN
PHONE:81-3-3491-9741
FAX
:81-3-3493-2933
The contents of this catalog are current as of June 2001. Contents are subject to change without notice for the purpose of improvements.