INFINEON V23815-K1306-M136

Fiber Optics
Parallel Optical Link:
PAROLI ® Tx AC, 1.25 Gbit/s
Parallel Optical Link:
PAROLI ® Rx AC, 1.25 Gbit/s
V23814-K1306-M136
V23815-K1306-M136
Features
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Power supply 3.3 V
Multistandard differential signal electrical interface
12 electrical data channels
Asynchronous, AC-coupled optical link
12 optical data channels
Transmission data rate of up to 1250 Mbit/s per
channel, total link data rate up to 15 Gbit/s
850 nm VCSEL array technology
PIN diode array technology
62.5 µm graded index multimode fiber ribbon
MT based optical port
SMD technology
OIF 1) compliant
IEC Class 1 laser safety compliant
GBE mask compliant
Optical Port
• Designed for the Simplex MT Connector (SMC)
• Port outside dimensions: 15.4 mm x 6.8 mm (width x height)
• MT compatible (IEC 61754-5) fiber spacing (250 µm) and alignment
pin spacing (4600 µm)
• Alignment pins fixed in module port
• Integrated mechanical keying
• Process plug (SMC dimensions) included with every module
1)
OIF-VSR4-01.0 Implementation Agreement (VSR OC-192/STM-64)
PAROLI® is a registered trademark of Infineon Technologies AG
Data Sheet
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2001-12-01
V23814-K1306-M136
V23815-K1306-M136
Applications
Features of the Simplex MT Connector (SMC)
(as part of optional PAROLI fiber optic cables)
•
•
•
•
•
Uses standardized MT ferrule (IEC 61754-5)
MT compatible fiber spacing (250 µm) and alignment pin spacing (4600 µm)
Snap-in mechanism
Ferrule bearing spring loaded
Integrated mechanical keying
Applications
Telecommunication
• Switching equipment
• Access network
Data Communication
• Interframe (rack-to-rack)
• Intraframe (board-to-board)
• On board (optical backplane)
Data Sheet
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V23814-K1306-M136
V23815-K1306-M136
Pin Configuration
Pin Configuration
The numbering conventions for the Tx and Rx modules are the same.
Numbering Conventions Transmitter/Receiver
Figure 1
Pin Description Transmitter
Pin
No.
1
2
3
4
5
6
Symbol
Level/ Logic
VCC
7
8
VEE
VIN
9
10
11
12
13
14
t.b.l.o.
t.b.l.o.
Power supply voltage of laser driver
to be left open
to be left open
to be left open
to be left open
LVCMOS Out Laser Controller Up
High = normal operation
Low = laser fault or –RESET low
Ground
Input VIN rail
CML: VIN = Reference supply (e.g. VCC)
LVPECL, LVDS: VIN = VEE
to be left open
to be left open
Ground
Ground
Data In
Data Input #1, inverted
Data In
Data Input #1, non-inverted
t.b.l.o.
t.b.l.o.
t.b.l.o.
t.b.l.o.
LCU
VEE
VEE
DI01N
DI01P
Data Sheet
Description
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V23815-K1306-M136
Pin Configuration
Pin Description Transmitter (cont’d)
Pin
No.
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
Symbol
Level/ Logic
VEE
VEE
DI02N
DI02P
Data In
Data In
VEE
VEE
DI03N
DI03P
Data In
Data In
VEE
VEE
t.b.l.o.
DI04N
DI04P
Data In
Data In
VEE
DI05N
DI05P
Data In
Data In
VEE
VEE
DI06N
DI06P
Data In
Data In
VEE
VEE
DI07N
DI07P
Data In
Data In
VEE
VEE
DI08N
DI08P
Data In
Data In
VEE
VEE
VEE
DI09N
DI09P
t.b.l.o.
Data Sheet
Data In
Data In
Description
Ground
Ground
Data Input #2, inverted
Data Input #2, non-inverted
Ground
Ground
Data Input #3, inverted
Data Input #3, non-inverted
Ground
Ground
to be left open
Data Input #4, inverted
Data Input #4, non-inverted
Ground
Data Input #5, inverted
Data Input #5, non-inverted
Ground
Ground
Data Input #6, inverted
Data Input #6, non-inverted
Ground
Ground
Data Input #7, inverted
Data Input #7, non-inverted
Ground
Ground
Data Input #8, inverted
Data Input #8, non-inverted
Ground
Ground
Ground
Data Input #9, inverted
Data Input #9, non-inverted
to be left open
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Pin Configuration
Pin Description Transmitter (cont’d)
Pin
No.
49
50
51
52
53
54
55
56
57
58
59
60
61
62
Symbol
Level/ Logic
VEE
VEE
DI10N
DI10P
Data In
Data In
VEE
VEE
DI11N
DI11P
Data In
Data In
VEE
VEE
DI12N
DI12P
Data In
Data In
VEE
VIN
63
64
t.b.l.o.
–RESET LVCMOS In
65
66
67
VEE
VEE
LE
LVCMOS In
68
–LE
LVCMOS In
69
70
71
72
t.b.l.o.
t.b.l.o.
t.b.l.o.
VCC
Data Sheet
Description
Ground
Ground
Data Input #10, inverted
Data Input #10, non-inverted
Ground
Ground
Data Input #11, inverted
Data Input #11, non-inverted
Ground
Ground
Data Input #12, inverted
Data Input #12, non-inverted
Ground
VIN rail
CML: VIN = Reference supply (e.g. VCC)
LVPECL, LVDS: VIN = VEE
to be left open
High = laser diode array is active
Low = switches laser diode array off
This input has an internal pull-down to ensure laser
safety switch off in case of unconnected
–RESET input
Ground
Ground
Laser ENABLE. High active.
High = laser array is on if –LE is also active.
Low = laser array is off. This input has an internal
pull-up, therefore can be left open.
Laser ENABLE. Low active. Low = laser array is on
if LE is also active. This input has an internal pulldown, therefore can be left open.
to be left open
to be left open
to be left open
Power supply voltage of laser driver
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Pin Configuration
Pin Description Receiver
Pin
No.
1
2
Symbol
Level/ Logic
VEE
VCC
3
VCC
4
5
t.b.l.o.
OEN
6
SD1
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
VCCO
VEE
Ground
Power supply voltage of preamplifier
and analog circuitry
Power supply voltage of preamplifier
and analog circuitry
to be left open
LVCMOS In
Output Enable
High = normal operation
Low = sets all Data Outputs to low
This input has an internal pull-up which pulls to high
level when this input is left open
LVCMOS Out Signal Detect on fiber #1.
High = signal of sufficient AC power is
present on fiber #1
Low = signal on fiber #1 is insufficient.
Power supply voltage of output stages
Ground
to be left open
Ground
Ground
Ground
LVDS Out
Data Output #1, non-inverted
LVDS Out
Data Output #1, inverted
Ground
Ground
LVDS Out
Data Output #2, non-inverted
LVDS Out
Data Output #2, inverted
Ground
Ground
LVDS Out
Data Output #3, non-inverted
LVDS Out
Data Output #3, inverted
Ground
Ground
to be left open
t.b.l.o.
VEE
VEE
VEE
DO01P
DO01N
VEE
VEE
DO02P
DO02N
VEE
VEE
DO03P
DO03N
VEE
VEE
t.b.l.o.
Data Sheet
Description
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V23814-K1306-M136
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Pin Configuration
Pin Description Receiver (cont’d)
Pin
No.
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
Symbol
Level/ Logic
Description
DO04P
DO04N
LVDS Out
LVDS Out
Data Output #4, non-inverted
Data Output #4, inverted
Ground
Data Output #5, non-inverted
Data Output #5, inverted
Ground
Ground
Data Output #6, non-inverted
Data Output #6, inverted
Ground
Ground
Data Output #7, non-inverted
Data Output #7, inverted
Ground
Ground
Data Output #8, non-inverted
Data Output #8, inverted
Ground
Ground
Ground
Data Output #9, non-inverted
Data Output #9, inverted
to be left open
Ground
Ground
Data Output #10, non-inverted
Data Output #10, inverted
Ground
Ground
Data Output #11, non-inverted
Data Output #11, inverted
Ground
Ground
VEE
DO05P
DO05N
LVDS Out
LVDS Out
VEE
VEE
DO06P
DO06N
LVDS Out
LVDS Out
VEE
VEE
DO07P
DO07N
LVDS Out
LVDS Out
VEE
VEE
DO08P
DO08N
LVDS Out
LVDS Out
VEE
VEE
VEE
DO09P
DO09N
t.b.l.o.
LVDS Out
LVDS Out
VEE
VEE
DO10P
DO10N
LVDS Out
LVDS Out
VEE
VEE
DO11P
DO11N
VEE
VEE
Data Sheet
LVDS Out
LVDS Out
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Pin Configuration
Pin Description Receiver (cont’d)
Pin
No.
59
60
61
62
63
64
65
66
67
Symbol
Level/ Logic
DO12P
DO12N
LVDS Out
LVDS Out
VEE
VEE
VEE
68
ENSD
69
70
t.b.l.o.
VCC
71
VCC
72
VEE
t.b.l.o.
VEE
VCCO
–SD12
Data Sheet
Description
Data Output #12, non-inverted
Data Output #12, inverted
Ground
Ground
Ground
to be left open
Ground
Power supply voltage of output stages
LVCMOS Out Signal Detect on fiber #12.
low active
Low = signal of sufficient AC power is present on
fiber #12.
High = signal on fiber #12 is insufficient.
LVCMOS In
Enable Signal Detect
High = SD1 and SD12 function enabled
Low = SD1 and SD12 are set to permanent active.
This input has an internal pull-up which pulls to high
level when this input is left open
to be left open
Power supply voltage of preamplifier
and analog circuitry
Power supply voltage of preamplifier
and analog circuitry
Ground
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V23814-K1306-M136
V23815-K1306-M136
Description
Description
PAROLI is a parallel optical link for high-speed data transmission. A complete PAROLI
system consists of a transmitter module, a 12-channel fiber optic cable, and a receiver
module.The transmitter supports LVDS, CML and LVPECL differential signals. The
receiver module is described for the LVDS electrical output only. A specification for
Infineon’s adjustable CML output can be provided separately.
Transmitter V23814-K1306-M136
The transmitter module converts parallel electrical input signals via a laser driver and a
Vertical Cavity Surface Emitting Laser (VCSEL) diode array into parallel optical output
signals. All input data signals are Multistandard Differential Signals (LVDS compatible;
they also support LVPECL and CML because of the wide common input range). The
electrical interface (LVDS, LVPECL or CML) is selected by the supply inputs VIN. The
data rate is up to 1250 Mbit/s for each channel.The transmitter module’s min. data rate
of 500 Mbit/s is specified for the CID 1) worst case pattern (disparity 72) or any pattern
with a lower disparity.
A logic low level at –RESET switches all laser outputs off. During power-up –RESET
must be used as a power-on reset which disables the laser driver and laser control until
the power supply has reached a 3.135 V level.
The Laser Controller Up (LCU) output is low if a laser fault is detected or –RESET is
forced to low.
All non data signals have LVCMOS levels.
Transmission delay of the PAROLI system is ˆ 1 ns for the transmitter, ˆ 1 ns for the
receiver and approximately 5 ns per meter for the fiber optic cable.
LE -LE laser enable
Electrical
Input
Data In
12
12
Input
Stage
Laser
Driver
12
Optical
Output
Laser
Diode
Array
12
Data
Laser
Control
VIN
Figure 2
1)
Laser Controller
Up (LCU)
-RESET
Transmitter Block Diagram
Consecutive Identical Digit (CID) immunity test pattern for STM-N signals.
ITU-T recommendation G.957 sec. II.
Data Sheet
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V23814-K1306-M136
V23815-K1306-M136
Description
Receiver V23815-K1306-M136
The PAROLI receiver module converts parallel optical input signals into parallel electrical
output signals. The optical signals received are converted into voltage signals by PIN
diodes, transimpedance amplifiers, and gain amplifiers. There are two different modules
available for LVDS and Infineon’s adjustable CML output. This description only refers to
a module with LVDS output. A module description for CML output can be provided
separately.
The data rate is up to 1250 Mbit/s for each channel. The receiver module’s min. data rate
of 500 Mbit/s is specified for the CID 1) worst case pattern (disparity 72) or any pattern
with a lower disparity.
Additional Signal Detect outputs (SD1 active high / SD12 active low) show whether an
optical AC input signal is present at data input 1 and/or 12. The signal detect circuit can
be disabled with a logic low at ENSD. The disabled signal detect circuit will permanently
generate an active level at Signal Detect outputs, even if there is insufficient signal input.
This could be used for test purposes.
A logic low at LVDS Output Enable (OEN) sets all data outputs to logic low. SD outputs
will not be effected.
All non data signals have LVCMOS levels.
Transmission delay of the PAROLI system is at a maximum 1 ns for the transmitter, 1 ns
for the receiver and approximately 5 ns per meter for the fiber optic cable.
Optical
Input
Electrical
Output
12
12
Data
Pin
Diode
Array
Gain
Amplifier
Amplifier
12
LVDS
Output
Stage
12
Signal
Detect
Circuit
ENSD
Figure 3
1)
Data out
SD1
-SD12
Output Enable (OEN)
Receiver Block Diagram
Consecutive Identical Digit (CID) immunity test pattern for STM-N signals,
ITU-T recommendation G.957 sec. II.
Data Sheet
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V23814-K1306-M136
V23815-K1306-M136
Laser Safety
Laser Safety
The transmitter of the AC coupled Parallel Optical Link (PAROLI) is an IEC 60825-1
Amend.2 Class 1 laser product. It complies with FDA performance standards (21 CFR
1040.10 and 1040.11) for laser products except for deviations pursuant to Laser Notice
No. 50, dated July 26, 2001. To avoid possible exposure to hazardous levels of invisible
laser radiation, do not exceed maximum ratings.
The PAROLI module must be operated under the specified operating conditions (supply
voltage can be adjusted between 3.0 V and 3.6 V) under any circumstances to ensure
laser safety.
Attention: Class 1 Laser Product
Note: Any modification of the module will be considered an act of “manufacturing”, and will
require, under law, recertification of the product under FDA (21 CFR 1040.10 (i)).
Laser aperture
and beam
Figure 4
Laser Emission
Laser Safety Design Considerations
To ensure laser safety for all input data patterns each channel is controlled internally and
will be switched off if the laser safety limits are exceeded.
A channel alerter switches the respective data channel output off if the input duty cycle
permanently exceeds 57%. The alerter will not disable the channel below an input duty
cycle of 57% under all circumstances.
The minimum alerter response time is 1 µs with a constant high input, i.e. in the input
pattern the time interval of excessive high input (e.g. ’1’s in excess of a 57% duty cycle,
consecutive or non-consecutive) must not exceed 1 µs, otherwise the respective channel
will be switched off. The alerter switches the respective channel from off to on without
the need of resetting the module if the input duty cycle is no longer violated.
All of the channel alerters operate independently, i.e. an alert within a channel does not
affect the other channels. To decrease the power consumption of the module unused
channel inputs can be tied to high input level. In this way a portion of the supply current
in this channel is triggered to shut down by the corresponding alerter.
Data Sheet
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V23814-K1306-M136
V23815-K1306-M136
Technical Data
Technical Data
Stress beyond the values stated below may cause permanent damage to the device.
Exposure to absolute maximum rating conditions for extended periods of time may affect
device reliability.
Absolute Maximum Ratings
Parameter
Symbol
VCC–VEE
V,1
|V,'|
T&$6(
T67*
Supply Voltage
Data/Control Input Levels 1)
Data Input Differential Voltage 2)
Operating Case Temperature 3)
Limit Values
min.
max.
–0.3
4.5
–0.5
VCC+0.5
80
–20
100
Operating Moisture
20
85
Storage Moisture
20
85
1
ESD Resistance
(all pins to VEE, human body model) 4)
1)
2)
3)
4)
V
2.0
0
Storage Ambient Temperature
Unit
°C
%
kV
At Data and LVCMOS inputs.
|VID| = |(input voltage of non-inverted input minus input voltage of inverted input)|.
Measured at case temperature reference point (see Package Outlines Figure 15).
To avoid electrostatic damage, handling cautions similar to those used for MOS devices must be observed.
Data Sheet
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V23814-K1306-M136
V23815-K1306-M136
Technical Data
Recommended Operating Conditions
Parameter
Symbol
Limit Values
min.
typ.
Unit
max.
Transmitter
Power Supply Voltage
Noise on Power Supply 1)
Noise on Power Supply 2)
Data Input Voltage Range 3) 4)
Data Input Differential Voltage 4) 5)
Data Input Skew 6)
Data Input Rise/Fall Time 7)
LVCMOS Input High Voltage
LVCMOS Input Low Voltage
LVCMOS Input Rise/Fall Time
8)
VCC
NPS1
NPS2
VDATAI
|VID|
tSPN
tR , tF
VLVCMOSIH
VLVCMOSIL
tR , tF
3.135
VCC
NPS1
NPS2
Rt
3.0
3.6
V
50
mV
100
500
VCC
80
1000
0.5 x tR, tF ps
50
400
2.0
VCC
VEE
0.8
V
20
ns
3.6
V
50
mV
Receiver
Power Supply Voltage
Noise on Power Supply 1)
Noise on Power Supply 2)
Differential LVDS
Termination Impedance
80
Optical Input Rise/Fall Time 9)
VLVCMOSIH 2.0
VLVCMOSIL VEE
tR , tF
tR , tF
Input Extinction Ratio
ER
6.0
Input Center Wavelength
lC
830
LVCMOS Input High Voltage
LVCMOS Input Low Voltage
LVCMOS Input Rise/Fall Time 8)
120
W
VCC
V
0.8
20
ns
ps
dB
860
nm
Voltages refer to VEE = 0 V.
1)
2)
3)
4)
5)
6)
7)
8)
9)
Noise frequency is 1 kHz to 10 MHz. Voltage is peak-to-peak value.
Noise frequency is > 10 MHz. Voltage is peak-to-peak value.
This implies that the input stage can be AC coupled.
Level diagram: see Figure 5
|VID| = |(input voltage of non-inverted input minus input voltage of inverted input)|.
Skew between positive and negative inputs measured at 50% level.
20% - 80% level.
Measured between 0.8 V and 2.0 V.
20% - 80% level. Non filtered values.
Data Sheet
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V23814-K1306-M136
V23815-K1306-M136
Technical Data
mV
VCC
|VID|
500
Time
Figure 5
Input Level Diagram
Transmitter Module
VCC
Data In P
internal P
Rin/2
Rin/2
Data In N
V
internal N
IN
>6 K
1.95 V
Figure 6
Data Sheet
Input Stage
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V23815-K1306-M136
Technical Data
The electro-optical characteristics described in the following tables are valid only for use
under the recommended operating conditions.
Transmitter Electrical Characteristics
Parameter
Symbol
Limit Values
min.
typ.
max.
Unit
Supply Current
ICC
350
450
mA
Power Consumption
P
1.2
1.6
W
Data Rate per Channel
DR
1250
Mbit/s
LVCMOS Output Voltage Low
VLVCMOSOL
VLVCMOSOH 2.5
ILVCMOSI –500
0.4
V
500
µA
0.5
mA
LVCMOS Output Voltage High
LVCMOS Input Current
High/Low
500 1)
LVCMOS Output Current High 2) ILVCMOSOH
LVCMOS Output Current Low 3)
Data Differential Input
Impedance 4)
Data Input Differential Current
1)
2)
3)
4)
ILVCMOSOL
RIN
80
120
W
|II|
5.5
mA
4.0
Specified for CID worst case pattern (disparity 72) or any pattern with a smaller disparity.
Source current.
Sink current.
Data input stage.
Data Sheet
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V23814-K1306-M136
V23815-K1306-M136
Technical Data
Transmitter Electro-Optical Characteristics
Parameter
Symbol
Limit Values
min.
typ.
max.
Launched Power Shutdown
tR
tF
JT
JD
tCSK
PAVG
PSD
Center Wavelength
lC
Spectral Width (FWHM)
Dl
2
Spectral Width (rms)
Dl
0.85
Relative Intensity Noise
RIN
–117
Extinction Ratio (dynamic)
ER
6.0
Optical Modulation Amplitude 4)
OMA
0.15 5)
Optical Rise Time
Optical Fall Time
1)
1)
Total Jitter 2)
Deterministic Jitter
Channel-to-channel skew 3)
Launched Average Power
Unit
200
ps
200
0.284
UI
0.1
–9.0
–5.0
100
ps
–3.0
dBm
–30.0
830
860
nm
dB/Hz
dB
0.46 6)
mW
GBE 7)
Eye mask compliance
Optical parameters valid for each channel.
1)
2)
3)
4)
5)
6)
7)
20% - 80% level, non filtered values.
Measured using a filter as defined in IEEE 802.3 (2000-edition) Gigabit Ethernet specification, section 38.6.5.
With input channel-to-channel skew 0 ps and a maximum data channel-to-channel average deviation and
swing deviation of 5%.
Peak to peak values.
Corresponds to a minimum extinction ratio of 6 dB.
Corresponds to a typical extinction ratio of 8 dB.
IEEE 802.3, sec. 38.6.5.
VCC
-RESET
3.6 V
3.135 V
2.0 V
0.8 V
t3
Data
data valid
data invalid
t1
Figure 7
Data Sheet
t2
Timing Diagram
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V23815-K1306-M136
Technical Data
Parameter
Symbol
Limit Values
min.
t1
t2
t3
–RESET on Delay Time
–RESET off Delay Time
–RESET Low Duration 1)
1)
Unit
max.
100
ms
50
µs
10
Only when not used as power on reset. At any failure recovery, –RESET must be brought to low level for at least t3.
Receiver Electrical Characteristics
Parameter
Symbol
Limit Values
min.
typ.
max.
Unit
Supply Current
ICC
250
350
mA
Power Consumption
P
0.8
1.3
W
LVDS Output Low Voltage 1), 2)
VLVDSOL
VLVDSOH
|VOD|
LVDS Output High Voltage 1), 2)
LVDS Output Differential
Voltage 1), 2), 3)
925
1475
LVDS Output Offset Voltage 1), 2), 4) VOS
250
400
1125
1275
tR , tF
VLVCMOSOL
LVCMOS Output Voltage Low
LVCMOS Output Voltage High VLVCMOSOH 2500
LVCMOS Input Current High/Low ILVCMOSI
–500
LVCMOS Output Current High 6) ILVCMOSOH
LVCMOS Output Current Low 7) ILVCMOSOL
Total Jitter 8), 9)
JT
JD
Deterministic Jitter 8)
10)
tCSK
Channel-to-channel skew
LVDS Rise/Fall Time 5)
1)
2)
3)
4)
5)
6)
7)
8)
9)
10)
mV
400
ps
400
mV
500
µA
0.5
mA
4.0
0.332
UI
0.08
100
ps
Level Diagram: see Figure 8
LVDS output must be terminated differentially with Rt.
|VOD| = |(output voltage of non-inverted output minus output voltage of inverted output)|.
VOS = 1/2 (output voltage of inverted output + output voltage of non-inverted output).
Measured between 20% and 80% level with a maximum capacitive load of 5 pF.
Source current.
Sink current.
With no optical input jitter.
At sensitivity limit of 0.028 mW OMA.
With input channel-to-channel skew 0 ps.
Data Sheet
17
2001-12-01
V23814-K1306-M136
V23815-K1306-M136
Technical Data
mV
1475
|VOD|
925
Time
Figure 8
Output Level Diagram
.
Receiver Electro-Optical Characteristics
Parameter
Symbol
Data Rate Per Channel
DR
Sensitivity (Average Power) 2)
PIN
Optical Modulation Amplitude
3)
Saturation (Average Power)
Signal Detect Assert Level 5)
Signal Detect Deassert Level 5)
Signal Detect Hysteresis 5)
Return Loss of Receiver
Limit Values
Unit
min.
max.
500 1)
1250
Mbit/s
–18.5
dBm
OMA
0.028 4)
mW
PSAT
PSDA
PSDD
PSDA
–PSDD
ARL
–3.0
dBm
–19.5
–29.0
1.0
4.0
dB
12
Optical parameters valid for each channel.
1)
2)
3)
4)
5)
Specified for CID worst case pattern (disparity 72) or any pattern with a smaller disparity.
BER = 10–12, Extinction ratio = infinite, Specified for CID worst case pattern (disparity 72) or any pattern with a
smaller disparity.
Peak to peak value.
Corresponds to an maximum sensitivity (average power) of –18.5 dBm at an infinite extinction ratio.
Extinction ratio = infinite,
PSDA: Average optical power when SD switches from inactive to active.
PSDD: Average optical power when SD switches from active to inactive.
Data Sheet
18
2001-12-01
V23814-K1306-M136
V23815-K1306-M136
Technical Data
Data Out 1, 12
t2
t1
Signal Detect 1
Signal Detect 12
Output Enable OEN
Data Out
2.0 V
0.8 V
data valid
t3
Figure 9
data valid
data Low
t4
Timing Diagrams
Parameter
Symbol
Max.
Unit
Signal Detect Deassert Time
t1
t2
t3
t4
10
µs
Signal Detect Assert Time
LVDS Output Enable off Delay Time
LVDS Output Enable on Delay Time
Data Sheet
19
10
20
ns
20
2001-12-01
V23814-K1306-M136
V23815-K1306-M136
Assembly
Assembly
On the next pages are some figures to assist the customer in designing his printed circuit
board (PCB). Figure 10 shows the mechanical dimensions of the PAROLI transmitter
and receiver modules and Figure 11 to Figure 13 give the dimensions of the holes and
solder pads on a customer PCB that are necessary to mount the modules on this PCB.
Keeping the tolerances for the PCB given in Figure 11 to Figure 13 is required to
properly attach the PAROLI transmitter and receiver module to the PCB.
Attachment to the customer PCB should be done with four M2 screws torqued to
0.25 Nm +0.05 Nm (see Figure 10, cross section B-B). The screw length a should be 3
to 4 mm plus the thickness b of the customer PCB.
Special care must be taken to remove residues from the soldering and washing process
which can impact the mechanical function. Avoid the use of aggressive organic solvents
like ketones, ethers, etc. Consult the supplier of the PAROLI modules and the supplier
of the solder paste and flux for recommended cleaning solvents.
The following common cleaning solvents will not affect the module: deionized water,
ethanol, and isopropyl alcohol. Air-drying is recommended to a maximum temperature
of 150°C. Do not use ultrasonics.
During soldering, heat must be applied to the leads only, to ensure that the case
temperature never exceeds 150°C. The module must be mounted with a hot-air or hotbar soldering process using a SnPb solder type, e.g. Sn62Pb36Ag2, in accordance with
ISO 9435.
Data Sheet
20
2001-12-01
V23814-K1306-M136
V23815-K1306-M136
Assembly
Dimensions in [mm] inches
Figure 10
Data Sheet
Drawing of the PAROLI Transmitter and Receiver Module
21
2001-12-01
V23814-K1306-M136
V23815-K1306-M136
Assembly
Dimensions in [mm] inches
Figure 11
Data Sheet
Recommended Circuit Board Layout: Transmitter
22
2001-12-01
V23814-K1306-M136
V23815-K1306-M136
Assembly
Dimensions in [mm] inches
Figure 12
Recommended Circuit Board Layout: Receiver
No electronic components are allowed on the customer PCB within the area covered by
the PAROLI module and the jumper used to attach a ribbon fiber cable.
Data Sheet
23
2001-12-01
V23814-K1306-M136
V23815-K1306-M136
Assembly
Dimensions in [mm] inches
Figure 13
Data Sheet
Mounting Hole, Detail Y (see Figure 11 and Figure 12)
24
2001-12-01
V23814-K1306-M136
V23815-K1306-M136
Assembly
CML, LVDS or LVPECL
SMC
Port
Link
Controller
PAROLI Tx module
Ribbon
Cables
PAROLI Rx module
Board-to-Board
Passive Optical
Backplane
PAROLI
Tx
Rx
Optical
Feed Through
I/O Board
Backplane
PAROLI
SMC
Port
SMC
Port
Tx module
Rx module
Ribbon Cable
CML,
LVDS or
LVPECL
CML,
LVDS or
LVPECL
Point-to-Point
Figure 14
Data Sheet
Applications
25
2001-12-01
V23814-K1306-M136
V23815-K1306-M136
Package Outlines
Package Outlines
Dimensions in [mm] inches
Figure 15
Data Sheet
26
2001-12-01
V23814-K1306-M136
V23815-K1306-M136
Revision History:
2001-12-01
DS0
Previous Version:
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Subjects (major changes since last revision)
Document’s layout has been changed: 2002-Aug.
For questions on technology, delivery and prices please contact the Infineon
Technologies Offices in Germany or the Infineon Technologies Companies and
Representatives worldwide: see our webpage at http://www.infineon.com.
Edition 2001-12-01
Published by Infineon Technologies AG,
St.-Martin-Strasse 53,
D-81541 München, Germany
© Infineon Technologies AG 2002.
All Rights Reserved.
Attention please!
The information herein is given to describe certain components and shall not be considered as warranted
characteristics.
Terms of delivery and rights to technical change reserved.
We hereby disclaim any and all warranties, including but not limited to warranties of non-infringement, regarding
circuits, descriptions and charts stated herein.
Infineon Technologies is an approved CECC manufacturer.
Information
For further information on technology, delivery terms and conditions and prices please contact your nearest
Infineon Technologies Office in Germany or our Infineon Technologies Representatives worldwide.
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Due to technical requirements components may contain dangerous substances. For information on the types in
question please contact your nearest Infineon Technologies Office.
Infineon Technologies Components may only be used in life-support devices or systems with the express written
approval of Infineon Technologies, if a failure of such components can reasonably be expected to cause the failure
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devices or systems are intended to be implanted in the human body, or to support and/or maintain and sustain
and/or protect human life. If they fail, it is reasonable to assume that the health of the user or other persons may
be endangered.