16 G FC Compliant 850 nm
SFP+ Limiting Transceiver
JSH Series
www.lumentum.com
Data Sheet
16 G FC Compliant 850 nm SFP+ Limiting Transceiver
The Lumentum 16 G 850 nm SFP+ Optical Transceiver is a full duplex, integrated fiber optic
transceiver that provides a high-speed serial link at 14.025 Gbps signaling rates. The
transceiver supports the enhanced small form factor pluggable module (SFP+) specification
SFF-8431 Rev. 4.1 for the low-speed electrical interface, SFF-8432 Rev. 5.0 for the
mechanical interface, and SFF-8472 Rev. 11.0 for the management interface.
The transceiver complies with the Fibre Channel FC-PI-5
1600-M5x-SN variants, and complies with 800-M5x-SN and
400-M5x-SN-I when using rate-select inputs.
It integrates the receive and transmit path on one module. On the
transmit side, the 14.025 Gbps serial data stream is passed from
the electrical connector and recovered and retimed through a
CDR to a laser driver. The laser driver biases and modulates an
850 nm vertical cavity surface-emitting laser (VCSEL), enabling
data transmission over up to 125 m of OM4 multimode fiber
through an industry-standard LC connector. On the receive side,
the 14.025 Gbps optical data stream is recovered from a PIN
photodetector through a transimpedance amplifier, post amplifier
and CDR, and passed to an output driver. This module features a
hot-pluggable SFI-compliant limiting electrical interface. It has an
enhanced digital diagnostic feature set to monitor real-time
transceiver performance. It also has transmit disable, loss of
signal, and transmitter fault functions.
Key Features
• 16 G Fibre Channel (FC) specification compliant
• 8 G and 4 G FC specification compliant under
rate-select control
• 850 nm VCSEL laser
• Up to 125 m reach over OM4 multimode fiber
• Operating temperature range of 0 to 70°C
• Maximum power dissipation of 1 W
• Single 3.3 V power supply
• Linear SFI AC-coupled electrical output interface
• Supports digital diagnostic monitoring
Applications
• Storage area networks (SAN)
−− FC switches and hubs
−− Host bus adapters
−− Network interface cards (NICs)
−− Mass storage system
• Computer cluster cross-connects
Compliance
• FC-PI-5 Fibre Channel standard
• SFF-8431 Rev 4.1
• SFF-8432 Rev 5.0
• SFF-8472 Rev 11.0
• Class 1 laser safety
• Tested in accordance with Telcordia GR-468
• RoHS 6/6
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2
16 G FC Compliant 850 nm SFP+ Limiting Transceiver
Section 1
Functional Description
The 16 G 850 nm SW SFP+ optical transceiver is a full duplex
serial electric, serial optical device with both transmit and receive
functions contained in a single module that provides a high-speed
serial link at 14.025 Gbps signaling rates. The transceiver
complies with Fibre Channel FC-PI-5 1600-M5x-SN variants when
the rate-select inputs are pulled high, and complies with
800-M5x-SN and 400-M5x-SN-I when the rate-select inputs are
pulled low. The transceiver supports the Enhanced Small Form
Factor Pluggable Module SFP+ specification SFF-8431 Rev. 4.1 for
the electrical interface, SFF-8432 Rev. 5.0 for the mechanical
interface, and SFF-8472 Rev. 11.0 for the management interface.
Figure 1 shows a block diagram.
VCCT
VEET
VCCR
ROSA
RD–
CDR
RD+
TIA
SCL
MCU
SDA
TD–
Laser
Driver
CDR
TD+
TOSA
RX_LOS
TX_FAULT
VEET
VEET
VEET
RS1
Figure 1. VCCT
TX_DIS
RS0
Inside the module, the differential signal passes through a signal
conditioner with equalization that compensates for input data
stream losses and deterministic jitter. The transmit CDR function
generates a clock that matches the incoming data bit rate
frequency of the electrical data input. The clock is phase aligned
by a phase locked loop (PLL) that samples the data in the center
of the data eye pattern.
The Tx signal conditioner’s output is input to the laser driver
circuit which transforms the small swing digital voltage to an
output modulation that drives a VCSEL laser. The optical signal is
engineered to meet the 16 G FC when the rate-select inputs are
pulled high and 8 G and 4 G FC specifications when the rateselect inputs are pulled low. Closed-loop control of the
transmitted laser power over temperature and voltage variations
is provided. The laser is coupled to a multimode optical fiber
through an industry-standard LC optical connector.
VEER
Transceiver Ground
Power Supply Sequence/
In-Rush Control Circuit
Transmitter
The transmitter path converts serial NRZ electrical data from
4.25 to 14.025 Gbps line rates to a standard compliant optical
signal. The transmitter accepts a 100 Ω differential 180 mV
peak-to-peak to 700 mV peak-to-peak CML electrical signal on
TD– and TD+ pins.
MOD_ABS
Receiver
The receiver converts incoming DC-balanced serial NRZ 4.25 to
14.025 Gbps line rate optical data into serial electrical signals.
The amplified signal is passed to a signal conditioning IC that
provides clock and data recovery. The receive CDR function
generates a clock that is at the same frequency as the incoming
data bit rate of the optical data input. The clock is phase aligned
by a PLL that samples the data in the center of the data eye
pattern. The CDR contains a lock detect circuit that indicates
successful locking of the PLL onto the incoming data.
The amplified signal is output directly on the RD+ and RD− pins
as a 100 Ω CML signal.
Lumentum SFP+ optical transceiver functional
block diagram
The transceiver has several low-speed interface connections.
These connections include: transmitter fault (Tx_Fault),
transmitter disable (Tx_Disable), rate select (RS0 and RS1),
module absent (Mod_ABS), receive loss of signal (Rx_LOS), and a
2-wire serial interface clock (SCL) and data (SDA).
The transceiver supports the SFI electrical interface. The
electrical interface is based on a high-speed, low-voltage logic
AC-coupled limiting interface with a 100 Ω nominal differential
impedance.
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3
16 G FC Compliant 850 nm SFP+ Limiting Transceiver
RS0 and RS1
Input pins. Pulled low to VEET with > 30 kΩ
resistors in the module. When RS1 is asserted low,
the transmitter CDR is bypassed and the module
transmitter is optimized for low-speed operation,
8.5 Gbps or lower. When RS0 is asserted low, the
receiver CDR is bypassed and the module receiver
is optimized for low-speed operation, 8.5 Gbps or
lower.
Mod_ABS
Output pin. Asserted high when the SFP+ module is
absent and is pulled low when the SFP+ module is
inserted.
Rx_LOS
Output pin. Asserted high when insufficient optical
power for reliable signal reception is received.
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2
2
TD +/−
Rx_LOS
Mod_ABS
Tx_Fault
2
OUTPUT
Tx_Disable
INPUT
RS1
Input pin. When asserted high or left open, the
transmitter output is turned off. When Tx_Disable is
asserted low or grounded, the module transmitter is
operating normally.
+3.3 V VCCT
Tx_Disable
POWER
RS0
Output pin. When asserted high, indicates that the
module has detected a transmitter fault condition
related to laser operation or safety.
SCL/SDA
2-wire serial interface clock and data line.
Tx_Fault
GND VEET
Definition
SCL/SDA
Application Schematics
SFP+ modules are hot pluggable and active connections are
powered by individual power connections for the transmitter
(VCC T) and the receiver (VCCR). Multiple modules can share a single
3.3 V power supply with individual filtering for each VCC T and
VCCR. The host shall generate an effective weighted integrated
spectrum RMS noise of less than 25 mV in the 10 Hz to 10 MHz
frequency range. Detailed power supply specifications are given
in SFF-8431 Rev. 4.1 Section 2.8. Figure 2 shows recommended
MSA connections to the Lumentum 16 G SFP+ optical transceiver.
GND VEER
Low-Speed Interface
Connections
Section 2
+3.3 V VCCR
Low-Speed Signaling
Low-speed signaling is based on low-voltage TTL (LVTTL)
operating at a nominal voltage of 3.3 V. Hosts should use a
pull-up resistor connected to VCC 3.3 V on the 2-wire interface
SCL, SDA, and all low-speed outputs based on the SFF 8431 Rev.
4.1 requirements.
SFP+ Module
RD +/−
Figure 2. Lumentum 16 G SFP+ optical transceiver application
schematic
4
16 G FC Compliant 850 nm SFP+ Limiting Transceiver
Section 3
Technical Specifications
Pin No.
Type
Name
Description
Section 3.1 Pin Function Definitions
1
—
VEET1
Module transmitter ground
Section 3.2 SFP+ SFI Reference Model Compliance Points
2
LVTTL-O
Tx_Fault2
Section 3.3 Absolute Maximum Ratings
Module transmitter fault; logic 1
indicates laser fault.
Section 3.4 Operating Conditions
3
LVTTL-I
Tx_Disable
Section 3.5 Electrical Characteristics
Transmitter disable; when asserted
high or left open, transmitter laser
source turned off.
Section 3.6
Electrical Jitter Specifications
4
LVTTL-I/O
SDA2
2-wire interface data line
Section 3.7 Timing Requirement of Control and Status I/O
5
LVTTL-I
SCL2
2-wire interface clock
6
—
Mod_ABS2
Indicates module is not present.
Grounded to VEET or VEER in the
module.
7
LVTTL-I
RS0
Rate select 0; logic low indicates an
8.5 Gbps receiver signal rate or
lower
8
LVTTL-O
Rx_LOS2
Receiver loss of signal
9
LVTTL-I
RS1
Rate select 1; logic low indicates an
8.5 Gbps transmitter signal rate or
lower
Table 1. 16 G SFP+ optical transceiver pin descriptions
Section 3.8
SFP+ 2-Wire Interface Protocol and Management
Interface
Section 3.9
Optical Transmitter Characteristics
Section 3.10
Optical Eye Mask
Section 3.11
Multimode Fiber Reaches
Section 3.12
Optical Receiver Characteristics
Section 3.13
Optical Characteristics Comparison at 8 G FC
and 4 G FC
Section 3.14
Regulatory Compliance
10
—
VEER1
Module receiver ground
PCB Layout
11
—
VEER1
Module receiver ground
Module Outline
12
CML-O
RD−
Receiver inverted data output
13
CML-O
RD+
Receiver non-inverted data output
14
—
VEER1
Module receiver ground
15
—
VCCR
Module receiver +3.3 V supply
16
—
VCC T
Module transmitter +3.3 V supply
17
—
VEET1
Module transmitter ground
Section 3.16
Section 3.17
Pin Function Definitions
11
VEER
12
RD–
13
RD+
14
VEER
15
VCCR
16
VCCT
17
VEET
18
TD+
19
TD–
20
VEET
VEER
10
18
CML-I
TD+
Transmitter non-inverted data input
RS1
9
19
CML-I
TD−
Transmitter inverted data input
Rx_LOS
8
20
—
VEET1
Module transmitter ground
RS0
7
MOD_ABS
SCL
6
SDA
4
Tx_Disable
3
Tx_Fault
2
VEET
1
5
Toward Bezel
Toward ASIC
3.1
Connectors
1. Module ground pins (GND) are isolated from the module case and chassis ground within the module
2. Shall be pulled up with 4.7 to 10 kΩ to a voltage between 3.15 V and 3.45 V on the host board
3.2
XFP/XFI Reference Model Compliance Points
D
C
Rx
ASIC/
SERDES
A
Figure 3. C'
Connector
Section 3.15
B'
SFP+ Module
Tx
B
16 G SFP+ optical transceiver host board pin assignments
Figure 4. www.lumentum.com
SFP+ optical transceiver model compliance points
5
16 G FC Compliant 850 nm SFP+ Limiting Transceiver
3.3
Absolute Maximum Ratings
Absolute maximum ratings represent the device’s damage thresholds. Permanent damage may occur if the device is stressed beyond
the limits stated here. Performance is not guaranteed and reliability is not implied for operation at any condition outside the
recommended operating limits.
Parameter
Symbol
Ratings
Unit
Storage temperature
TST
−40 to +85
°C
Operating case temperature
TOP
0 to +70
°C
Relative humidity
RH
5 to 85 (noncondensing)
%
Static electrical discharge (human body model)
ESD
1000 (high-speed lines)
2000 (low-speed lines)
V
Power supply voltages
VCC T, VCCR, max
−0.3 to 4.0
V
Receive input optical power (damage threshold)
Pdth
+3
dBm
3.4
Operating Conditions
Performance is not guaranteed and reliability is not implied for operation at any condition outside the operating limits.
Parameter
Min
Max
Unit
Operating case temperature rating
0
+70
°C
3.5
Electrical Characteristics
Parameter
Symbol
Min.
Typ.
Max.
Unit
Notes
Voltage
VCC
3.14
3.3
3.47
V
With respect to GND
Supply current
—
—
—
290
mA
—
Power dissipation
Pwr
—
—
1.0
W
—
Supply currents and voltages
Low-Speed Control and Sense Signals (detailed specification in SFP+ MSA SFF-8431 Rev. 4.1)
Outputs (Tx_Fault, Rx_LOS)
Inputs (Tx_Disable, RS0, RS1)
SCL and SDA inputs
VOL
−0.3
—
0.4
V
At 0.7 mA
IOH
−50
—
37.5
μA
Measured with a 4.7 kΩ load pulled up to VCC_host
VIL
−0.3
—
0.8
V
TX_Disable is pulled up in module to VCC T with 10 kΩ
VIH
2
—
Vcc3 + 0.3
V
RS0 and RS1 are pulled down to VEET in module with >30 kΩ
VIL
−0.3
—
Vcc3 * 0.3
V
Vcc3 * 0.7
—
Vcc3 + 0.5
V
VIH
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Rpullup pulled to VCC-host
6
16 G FC Compliant 850 nm SFP+ Limiting Transceiver
3.6
Electrical Jitter Specifications
Parameter
Symbol
Min
Max
Unit
Notes
Transmitter Electrical Input Signal Tolerance from Host at B” (detailed specification in FC-PI-5 Rev 6.1, FC-MJSQ, and FC-MSQS)
Independent deterministic jitter
DJ
—
0.31
UI(p-p)
Input data-dependent pulsewidth shrinkage
DDPWS
—
0.11
UI(p-p)
JSPAT pattern, BER < 1x10-12, at 14.025 Gbps
Uncorrelated jitter
UJ
—
0.03
UI(rms)
See FC-MSQS
Total input jitter
TJ
—
0.45
UI(p-p)
JSPAT pattern, BER < 1x10-12, at 14.025 Gbps
Eye mask
X1
—
0.03
UI
X2
—
0.045
UI
Y1
90
0.225
mV
Y2
—
350
mV
Reference FC-PI-5
Receiver Electrical Output Signal to Host at C’ (detailed specification in FC-PI-5 Rev 6.1, FC-MJSQ, and FC-MSQS)
Output deterministic jitter
DJ
—
0.22
UI(p-p)
Output data dependent pulsewidth shrinkage
DDPWS
—
0.14
UI(p-p)
JSPAT pattern, BER < 1x10-12, at 14.025 Gbps
Total jitter
TJ
—
0.70
UI
—
Eye mask
X1
X2
—
—
0.18
0.5
UI
UI
Reference FC-PI-5
Differential peak-to-peak voltage
Vp-p
340
850
mV
3.7
Timing Requirement of Control and Status I/O
Parameter
Symbol
Min
Max
Unit
Notes
Tx_Disable assert time
t_off
—
100
µs
Rising edge of Tx_Disable to fall of output signal below 10%
of nominal
Tx_Disable negate time
t_on
—
50
ms
Falling edge of Tx_Disable to rise of output signal above
90% of nominal1
Time to initialize 2-wire interface
t_2w_start_up
—
300
ms
Time to initialize
t_start_up_cooled
—
90
s
From power on or hot plug
Tx_Fault assert
Tx_Fault_on _cooled
—
50
ms
From occurrence of fault to assertion of Tx_Fault
Tx_Fault reset
Tx_Fault_reset
10
—
µs
Time Tx_Disable must be held high to reset Tx_Fault
Rx_LOS assert delay
t_loss_on
—
100
µs
From occurrence of loss of signal to assertion of R x_LOS
t_loss_off
—
100
µs
From occurrence of return of signal to negation of RX_LOS
RX_LOS negate delay
1. The transceiver is thermally stabilized prior to Tx _Disable negating event.
3.8
2-Wire Interface Protocol and Management Interface
The Lumentum SFP+ optical transceiver incorporates a 2-wire management interface, compliant with the SFF-8472 Rev 11.0
specification, which is used for serial ID, digital diagnostics, and certain control functions.
Rate Identifier (user ID address A0h, Byte 13) is used to control the independent Tx and Rx Rate Select function through software. The
timing and functionality is defined in the SFF-8472 Rev 11.0 specification.
The MSA explicitly describes the details of the protocol and interface. Please refer to the MSA for design reference.
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7
16 G FC Compliant 850 nm SFP+ Limiting Transceiver
3.9
Optical Transmitter Characteristics1
Parameter
Symbol
Min.
Typ.
Max.
Unit
Average optical power2
Pavg
−7.8
—
−1.0
dBm
Optical modulation amplitude (OMA)3
OMA
−4.8
—
—
dBm
Extinction ratio (informative)
ER
3.85
—
—
dB
Center wavelength
λ
840
—
860
nm
RMS spectral width2
—
—
—
0.59
nm
Vertical eye closure penalty
VECP
—
—
2.56
dB
Relative intensity noise
RIN12OMA
—
—
–128
dB/Hz
Symbol
Min.
Typ.
Max.
Unit
X1
—
0.25
UI
dBm
X2
—
0.40
UI
dB
X3
—
0.45
UI
nm
Y1
—
0.32
—
nm
Y2
—
0.35
—
dB
Y3
—
0.40
—
dB/Hz
3.10
Optical Eye Mask
Parameter
Transmitter optical output
Eye mask4
1. These specifications are applicable within the operating case temperature range specified in Section 3.4.
2. For 16 G FC operation when RS1 is high
3. Tested with PRBS 231 – 1 pattern
4. Reference FC-PI-5
Figure 5. www.lumentum.com
16 G SFP+ optical transmitter eye mask
8
16 G FC Compliant 850 nm SFP+ Limiting Transceiver
3.11
Multimode Fiber Reaches
Data Rate (Mbps)
Fiber Type
Variant Name
Reach (m)
Line Budget (dB)
Overfilled Modal Bandwidth –
Length at 850 nm (MHz*km)
1600
OM2
1600-M5-SN-S
0.5 – 35
1.63
500
OM3
1600-M5E-SN-I
0.5 – 100
1.86
1500
OM4
1600-M5F-SN-I
0.5 – 125
1.95
3500
OM2
800-M5-SN-S
0.5 – 50
1.68
500
OM3
800-M5E-SN-I
0.5 – 150
2.04
1500
OM4
800-M5F-SN-I
0.5 – 190
2.19
3500
OM2
400-M5-SN-I
0.5 – 150
2.06
500
OM3
400-M5E-SN-I
0.5 – 380
2.88
1500
OM4
400-M5F-SN-I
0.5 - 400
2.95
3500
800
400
3.12
Optical Receiver Characteristics1
Parameter
Symbol
Min.
Typ.
Max.
Unit
Center wavelength
λ
840
—
860
nm
Unstressed receiver sensitivity (OMA)
—
—
—
−10.5
dBm
Stressed jitter tolerance test (OMA)2
—
—
—
−6.7
dBm
Stressed receiver sensitivity (OMA)
—
—
—
−7.7
dBm
Receive overload2
Pmax
0
—
—
dBm
Return loss
—
12
—
—
dB
LOS assert
Plos_on
–31
—
—
dBm
LOS deassert
Plos_off
—
—
−11
dBm
LOS hysteresis
—
0.5
—
4
dB
3.13
Optical Characteristics Comparison at 8 G FC and 4 G FC
Min.
800-SN
Max.
Min.
400-SN
Max.
−1.0
−8.2
−1.0
−9.0
−1.0
−4.8
—
−5.2
—
–6.1
—
—
0.59
—
0.65
—
0.65
dBm
—
−10.5
—
−11.2
—
−12.1
R x jitter tolerance (OMA)
dBm
—
−6.7
—
−7.0
—
−8.1
Stressed receiver sensitivity
dBm
—
−7.7
—
−8.2
—
−8.6
Parameter
Unit
Min.
Average optical power
dBm
−7.8
Optical modulation amplitude
dBm
RMS spectral width
nm
Unstressed receiver sensitivity (OMA)
1600-SN
Max.
1.These specifications are applicable within the operating case temperature range specified in Section 3.4.
2.Guaranteed at 14.025 Gbps; measured with worst ER; BER<10 -12; PRBS 231 – 1 pattern
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9
16 G FC Compliant 850 nm SFP+ Limiting Transceiver
3.14
Regulatory Compliance
The transceiver complies with international safety and electromagnetic compatibility (EMC) requirements and standards. EMC
performance depends on the overall system design. The transceiver uses lead-free solder and is RoHS 6/6 compliant.
Table 2
Regulatory Compliance
Feature
Test Method
Performance
Safety
Product safety
UL 60950-1
CSA C22.2 No. 60950-1
Laser
UL recognized component for US and CAN
EN 60950-1
TUV certificate
IEC 60950-1
CB certificate
Flame Class V-0
Passes needle point flame test for component flammability verification
Low-Voltage Directive 2006/95/EC
Certified to harmonized standards listed; Declaration of Conformity issued
EN 60825-1, EN 60825-2
TUV certificate
IEC 60825-1
CB certificate
U.S. 21 CFR 1040.10
FDA/CDRH certified with accession number
Electromagnetic Compatibility
Radiated emissions
EMC Directive 2004/108/EC
FCC rules 47 CFR Part 15
CISPR 22
AS/NZS CISPR22
EN 55022
ICES-003, Issue 5
Class B digital device with a minimum −2 dB margin to the limit. Final margin may vary
depending on system implementation.
Tested frequency range: 30 MHz to 40 GHz or 5th harmonic (5 times the highest
frequency), whichever is less.
Requires good system EMI design practice to achieve Class B margins at the system
level.
VCCI regulations
Immunity
EMC Directive 2004/108/EC
CISPR 24
Certified to harmonized standards listed; Declaration of Conformity issued.
EN 55024
ESD
IEC/EN 61000-4-2
Exceeds requirements. Withstands discharges of ± 8 k V contact, ±15 k V air.
Radiated immunity
IEC/EN 61000-4-3
Exceeds requirements. Field strength of 10 V/m from 80 MHz to 6 GHz.
No detectable effect on transmitter/receiver performance between these limits.
Restriction of Hazardous Substances (RoHS)
RoHS
EU Directive 2011/65/EU
Compliant per the European Parliament Directive 2011/65/EU of the 8 June 2011
on the restricted use of certain hazardous substances in electrical and electronic
equipment (recast).
An RoHS Certificate of Conformance (C of C) is available upon request.
The product may use certain RoHS exemptions.
3.15
PCB Layout
Recommended PCB layout is given in SFP+ MSA SFF8431 Rev. 4.1.
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10
16 G FC Compliant 850 nm SFP+ Limiting Transceiver
3.16
Module Outline
3.17Connectors
Fiber
The SFP+ module has a duplex LC receptacle connector.
Electrical
The electrical connector is a 20-way, two-row PCB edge connector. The customer connector is Tyco/AMP Part No. 188247
or equivalent.
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11
16 G FC Compliant 850 nm SFP+ Limiting Transceiver
Section 4
Other Related Information
Section 4.1
Packing and Handling Instructions
Section 4.2
Electrostatic Discharge
Section 4.3
Laser Safety
4.1
Package and Handling Instructions
Connector Covers
The transceiver is supplied with an LC duplex receptacle. The
connector plug supplied protects the connector during standard
manufacturing processes and handling by preventing
contamination from dust, aqueous solutions, body oils, or
airborne particles.
Note: It is recommended that the connector plug remain on
whenever the transceiver optical fiber connector is not inserted.
Recommended Cleaning and Degreasing Chemicals
Lumentum recommends the use of methyl, isopropyl, and
isobutyl alcohols for cleaning.
Test and Operation
In most applications, the optical connector will protrude through
the system chassis and be subjected to the same ESD
environment as the system. Once properly installed in the
system, this transceiver should meet and exceed common ESD
testing practices and fulfill system ESD requirements.
Typical of optical transceivers, this module’s receiver contains a
highly sensitive optical detector and amplifier which may become
temporarily saturated during an ESD strike. This could result in a
short burst of bit errors. Such an event might require that the
application re-acquire synchronization at the higher layers (for
example, a serializer/deserializer chip).
4.3
Laser Safety
The transceiver is certified as a Class 1 laser product per
international standard IEC 60825-1:2007 2nd edition and is
considered non-hazardous when operated within the limits of
this specification.
The transceiver complies with 21 CFR 1040.10 except for
deviations pursuant to Laser Notice No. 50 dated June 24, 2007.
Do not use halogenated hydrocarbons, such as trichloroethane or
ketones such as acetone, chloroform, ethyl acetate, MEK,
methylene chloride, methylene dichloride, phenol, and
N-methylpyrrolidone.
This product is not designed for aqueous wash.
Housing
The transceiver housing is made from zinc.
4.2
Electrostatic Discharge
Handling
Normal electrostatic discharge (ESD) precautions are required
during the handling of this module. This transceiver is shipped in
ESD protective packaging. It should be removed from the
packaging and otherwise handled in an ESD protected
environment utilizing standard grounded benches, floor mats,
and wrist straps.
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Caution
Operating this product in a manner inconsistent with intended
usage and specifications may result in hazardous radiation
exposure.
Use of controls or adjustments or performance of procedures
other than these specified in this product data sheet may result
in hazardous radiation exposure.
Tampering with this laser product or operating this product
outside the limits of this specification may be considered an
‘act of manufacturing’ and may require recertification of the
modified product.
12
Ordering Information
For more information on this or other products and their availability, please contact your local Lumentum account manager or
Lumentum directly at customer.service@lumentum.com.
Description
Product Code
16 G FC, 125 m reach, limiting, 850 nm, commercial temperature range, SFP+ optical transceiver
JSH-14SWAA1
North America
Toll Free: 844 810 LITE (5483)
Outside North America
Toll Free: 800 000 LITE (5483)
China
Toll Free: 400 120 LITE (5483)
© 2015 Lumentum Operations LLC
Product specifications and descriptions in this
document are subject to change without notice.
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