HP HFBR-5720LP Fibre channel 2.125/1.0625 gbd 850 nm small form pluggable low voltage (3.3 v) optical transceiver Datasheet

Agilent HFBR-5720L/5720LP
Fibre Channel 2.125/1.0625 GBd 850 nm
Small Form Pluggable Low Voltage (3.3 V)
Optical Transceiver
Data Sheet
Description
The HFBR-5720L optical
transceiver from Agilent
Technologies offers maximum
flexibility to Fibre Channel
designers, manufacturers, and
system integrators to implement a
range of solutions for multimode
Fibre Channel applications. In order
to provide a wide range of system
level performance, without the need
for a data rate select input, this
product is fully compliant with all
equipment meeting the Fibre
Channel FC-PI 200-M5-SN-I and
200-M6-SN-I 2.125 GBd
specifications, and is compatible
with the Fibre Channel FC-PI 100M5-SN-I and FC-PI 100-M6-SN-I,
FC-PH2 100-M5-SN-I, and the FCPH2 100-M6-SN-I 1.0625 GBd
specifications.
Module Package
The transceiver meets the Small
Form Pluggable (SFP) industry
standard package utilizing an
integral LC-Duplex optical interface
connector. The hot-pluggable
capability of the SFP package
allows the module to be installed
at any time – even with the host
system operating and on-line.
This allows for system
configuration changes or
maintenance without system
down time. The HFBR-5720L
uses a reliable 850 nm VCSEL
source and requires a 3.3 V DC
power supply for optimal design.
Module Diagrams
Figure 1 illustrates the major
functional components of the
HFBR-5720L. The connection
diagram of the module is shown
in Figure 2. Figure 7 depicts the
external configuration and
dimensions of the module.
Installation
The HFBR-5720L can be installed
in or removed from any
MultiSource Agreement (MSA)compliant Small Form Pluggable
port regardless of whether the
host equipment is operating or
not. The module is simply
inserted, electrical interface first,
under finger pressure. Controlled
Features
• Compliant with 2.125 GBd Fibre
Channel FC-PI standard
• FC-PI 200-M5-SN-I for 50/125 µm
multimode cables
• FC-PI 200-M6-SN-I for 62.5/125 µm
multimode cables
• Compliant with 1.0625 GBd VCSEL
operation for both 50/125 and 62.5/125 µm
multimode cables
• Industry standard Small Form Pluggable
(SFP) package
• LC-Duplex connector optical interface
• Link lengths at 2.125 GBd:
0.5 to 300 m – 50/125 µm MMF
0.5 to 150 m – 62.5/125 µm MMF
• Link lengths at 1.0625 GBd:
0.5 to 500 m – 50/125 µm MMF
0.5 to 300 m – 62.5/125 µm MMF
• Reliable 850 nm Vertical Cavity Surface
Emitting Laser (VCSEL) source
technology
• Laser AEL Class 1 (eye safe) per:
US 21 CFR (J)
EN-60825-1 (+A11+A2)
• Single 3.3 V power supply operation
• De-latch options:
– HFBR-5720L standard de-latch
– HFBR-5720LP extended de-latch
Applications
• Mass storage system I/O
• Computer system I/O
• High speed peripheral interface
• High speed switching systems
• Host adapter I/O
• RAID cabinets
Related Products
• HFBR-5602: 850 nm 5 V Gigabit Interface
Converter (GBIC) for Fibre Channel FC-PH-2
• HFBR-53D3: 850 nm 5 V 1 x 9 laser transceiver for Fibre Channel FC-PH-2
• HFBR-5910E: 850 nm 3.3 V SFF laser transceiver for Fibre Channel FC-PH-2
• HDMP-2630/2631: 2.125/1.0625 Gbps TRx
family of SerDes IC
hot-plugging is ensured by design
and by 3-stage pin sequencing at
the electrical interface. The
module housing makes initial
contact with the host board EMI
shield mitigating potential
damage due to Electro-Static
Discharge (ESD). The 3-stage pin
contact sequencing involves (1)
Ground, (2) Power, and then (3)
Signal pins, making contact with
the host board surface mount
connector in that order. This
printed circuit board card-edge
connector is depicted in Figure 2.
Serial Identification (EEPROM)
The HFBR-5720L complies with
an industry standard MSA that
defines the serial identification
protocol. This protocol uses the
2-wire serial CMOS E2PROM
protocol of the ATMEL
AT24C01A or equivalent. The
HFBR-5720L BLOCK DIAGRAM
RECEIVER
LIGHT FROM FIBER
ELECTRICAL INTERFACE
AMPLIFICATION
& QUANTIZATION
PHOTO-DETECTOR
RD+ (RECEIVE DATA)
RD– (RECEIVE DATA)
LOSS OF SIGNAL
OPTICAL INTERFACE
TRANSMITTER
LIGHT TO FIBER
Tx_DISABLE
LASER
DRIVER &
SAFETY
CIRCUITRY
VCSEL
TD+ (TRANSMIT DATA)
TD– (TRANSMIT DATA)
Tx_FAULT
MOD-DEF2
EEPROM
MOD-DEF1
MOD-DEF0
Figure 1. Transceiver functional diagram.
20
VEET
1
VEET
19
TD–
2
TxFAULT
18
TD+
3
Tx DISABLE
17
VEET
4
MOD-DEF(2)
16
VCCT
5
MOD-DEF(1)
15
VCCR
6
MOD-DEF(0)
14
VEER
7
RATE SELECT
13
RD+
8
LOS
12
RD–
9
VEER
11
VEER
10
VEER
TOP OF BOARD
BOTTOM OF BOARD
(AS VIEWED THROUGH TOP OF BOARD)
Figure 2. Connection diagram of module printed circuit board.
2
contents of the HFBR-5720L
serial ID memory are defined in
Table 10 as specified in the SFP
MSA.
Tx Fault
The HFBR-5720L module
features a transmit fault control
signal output which when high
indicates a laser transmit fault
has occurred and when low
indicates normal laser operation.
A transmitter fault condition can
be caused by deviations from the
recommended module operating
conditions or by violation of eye
safety conditions. A fault is
cleared by cycling the Tx Disable
control input.
Transmitter Section
The transmitter section includes
the transmitter optical
subassembly (TOSA) and laser
driver circuitry. The TOSA,
containing an 850 nm VCSEL
(Vertical Cavity Surface Emitting
Laser) light source, is located at
the optical interface and mates
with the LC optical connector.
The TOSA is driven by a custom
silicon IC, which converts
differential logic signals into an
analog laser diode drive current.
This Tx driver circuit regulates
the optical power at a constant
level provided the data pattern is
valid 8B/10B balanced code.
Eye Safety Circuit
For an optical transmitter device
to be eye-safe in the event of a
single fault failure, the
transmitter will either maintain
normal eye-safe operation or be
disabled. In the event of an eye
safety fault, the VCSEL will be
disabled.
Tx Disable
Receiver Section
The receiver section includes the
receiver optical subassembly
(ROSA) and amplification/
quantization circuitry. The ROSA,
containing a PIN photodiode and
custom transimpedance
preamplifier, is located at the
optical interface and mates with
the LC optical connector. The
ROSA is mated to a custom IC
that provides post-amplification
and quantization. This circuit also
NORMALIZED AMPLITUDE
The HFBR-5720L accepts a
transmit disable control signal
input which shuts down the
transmitter. A high signal
implements this function while a
low signal allows normal laser
operation. In the event of a fault
(e.g., eye safety circuit activated),
cycling this control signal resets
the module as depicted in
Figure 6. The Tx Disable control
should be actuated upon
initialization of the module.
1.3
1.0
0.8
0.5
0.2
0
–0.2
0
x1
0.4
0.6
1-x1
1.0
NORMALIZED TIME
Figure 3. Transmitter eye mask diagram and typical transmitter eye.
3
includes a loss of signal (LOS)
detection circuit which provides
an open collector logic high
output in the absence of a usable
input optical signal level.
Loss of Signal
The Loss of Signal (LOS) output
indicates that the optical input
signal to the receiver does not
meet the minimum detectable
level for Fibre Channel compliant
signals. When LOS is high it
indicates loss of signal. When
LOS is low it indicates normal
operation. The Loss of Signal
thresholds are set to indicate a
definite optical fault has occurred
(e.g., disconnected or broken
fiber connection to receiver,
failed transmitter).
Functional Data I/O
Agilent’s HFBR-5720L fiber-optic
transceiver is designed to accept
industry standard differential
signals. In order to reduce the
number of passive components
required on the customer’s board,
Agilent has included the
functionality of the transmitter
bias resistors and coupling
capacitors within the fiber optic
module. The transceiver is
compatible with an “AC-coupled”
configuration and is internally
terminated. Figure 1 depicts the
functional diagram of the HFBR5720L.
Caution should be taken for the
proper interconnection between
the supporting Physical Layer
integrated circuits and the HFBR5720L. Figure 4 illustrates the
recommended interface circuit.
Several MSA compliant control
data signals are implemented in
the module and are depicted in
Figure 6.
Application Support
Evaluation Kit
To help you in your preliminary
transceiver evaluation, Agilent
offers a 2.125 GBd Fibre Channel
evaluation board. This board will
allow testing of the fiber-optic
VCSEL transceiver. Please
contact your local field sales
representative for availability and
ordering details.
Reference Designs
Reference designs for the HFBR5720L fiber-optic transceiver and
the HDMP-2630/2631 physical
layer IC are available to assist the
equipment designer. Figure 4
depicts a typical application
configuration, while Figure 5
depicts the MSA power supply
filter circuit design. All artwork is
available at the Agilent Website.
Please contact your local field
sales engineer for more
information regarding application
tools.
Regulatory Compliance
See Table 1 for transceiver
Regulatory Compliance
performance. The overall
equipment design will determine
the certification level. The
transceiver performance is
offered as a figure of merit to
assist the designer.
Electrostatic Discharge (ESD)
There are two conditions in which
immunity to ESD damage is
important. Table 1 documents our
immunity to both of these
4
conditions. The first condition is
during handling of the transceiver
prior to insertion into the
transceiver port. To protect the
transceiver, it is important to use
normal ESD handling
precautions. These precautions
include using grounded wrist
straps, work benches, and floor
mats in ESD controlled areas.
The ESD sensitivity of the HFBR5720L is compatible with typical
industry production
environments. The second
condition is static discharges to
the exterior of the host
equipment chassis after
installation. To the extent that the
duplex LC optical interface is
exposed to the outside of the host
equipment chassis, it may be
subject to system-level ESD
requirements. The ESD
performance of the HFBR-5720L
exceeds typical industry
standards.
Immunity
Equipment hosting the HFBR5720L modules will be subjected
to radio-frequency electromagnetic fields in some
environments. These transceivers
have good immunity to such
fields due to their shielded
design.
Electromagnetic Interference (EMI)
Most equipment designs utilizing
these high-speed transceivers
from Agilent Technologies will be
required to meet the
requirements of FCC in the
United States, CENELEC
EN55022 (CISPR 22) in Europe
and VCCI in Japan.
The metal housing and shielded
design of the HFBR-5720L
minimize the EMI challenge
facing the host equipment
designer. These transceivers
provide superior EMI
performance. This greatly assists
the designer in the management
of the overall system EMI
perfornmance.
Eye Safety
These 850 nm VCSEL-based
transceivers provide Class 1 eye
safety by design. Agilent
Technologies has tested the
transceiver design for compliance
with the requirements listed in
Table 1 under normal operating
conditions and under a single
fault condition.
Flammability
The HFBR-5720L VCSEL
transceiver housing is made of
metal and high strength, heat
resistant, chemically resistant,
and UL 94V-0 flame retardant
plastic.
Caution
There are no user serviceable
parts nor any maintenance
required for the HFBR-5720L.
Tampering with or modifying the
performance of the HFBR-5720L
will result in voided product
warranty. It may also result in
improper operation of the HFBR5720L circuitry, and possible
overstress of the laser source.
Device degradation or product
failure may result. Connection of
the HFBR-5720L to a nonapproved optical source,
operating above the recommended absolute maximum conditions
or operating the HFBR-5720L in
a manner inconsistent with its
design and function may result in
hazardous radiation exposure and
may be considered an act of
modifying or manufacturing a
laser product. The person(s)
performing such an act is
required by law to re-certify and
re-identify the laser product
under the provisions of U.S. 21
CFR (Subchapter J) and the TUV.
Ordering Information
Please contact your local field
sales engineer or one of the
Agilent Technologies franchised
distributors for ordering
information. For additional
technical information associated
with this product, including the
MSA, please visit Agilent
Technologies Semiconductor
Products Website at
www.agilent.com/view/fiber
Use the Quick Search feature to
search for this part number.
Agilent Technologies
Semiconductor Products
Customer Response Center is
also available to assist you at
1-800-235-0312.
Table 1. Regulatory Compliance
Feature
Electrostatic Discharge (ESD)
to the Electrical Pins
Electrostatic Discharge (ESD)
to the Duplex LC Receptacle
Test Method
MIL-STD-883C Method 3015.4
Performance
Class 2 (>2000 Volts)
Variation of IEC 61000-4-2
Electromagnetic Interference
(EMI)
Immunity
FCC Class B
CENELEC EN55022 Class B
(CISPR 22A)
VCCI Class 1
Variation of IEC 61000-4-3
Typically withstand at least 25 kV without
damage when the duplex LC connector
receptacle is contacted by a Human Body
Model probe.
System margins are dependent on customer
board and chassis design.
Eye Safety
US FDA CDRH AEL Class 1
Note 1
Component Recognition
Typically shows a negligible effect from a
10 V/m field swept from 80 to 1000 MHz
applied to the transceiver without a chassis
enclosure.
CDRH File # 9720151-16 (HFBR-5720L)
CDRH File # Pending (HFBR-5720LP)
EN 60950 Class 1
EN (IEC) 60825-1:1994+A11+A2
TUV File # E2171216.01 (HFBR-5720L)
EN (IEC) 60825-2:1994+A1
TUV File # Pending
(HFBR-5720LP)
Underwriters Laboratories and
UL file # E173874
Canadian Standards Association
Joint Component Recognition for
Information Technology Equipment
Including Electrical Business Equipment
Note:
1. Units manufactured prior to August 1, 2001 were certified to the previous TUV standard EN60825-1:1994+A11.
5
1 µH
3.3 V
10 µF
0.1 µF
1 µH
3.3 V
VCC,T
HFBR-5720L/LP
0.1 µF
4.7 K to 10 K
4.7 K to 10 K
Tx_DISABLE
GP04
Tx_FAULT
Tx_FAULT
VREFR
VREFR
SO+
TX[0:9]
SO–
50 Ω
TD+
50 Ω
TD–
100
TX GND
TBC
EWRAP
TBC
EWRAP
4.7 K to 10 K
HDMP-2630/31
PROTOCOL
IC
10 µF
RX[0:9]
RBC
Rx_RATE
REFCLK
RBC
Rx_RATE
SI+
SI–
0.1
µF
50 Ω
RD+
50 Ω
RD–
Rx_LOS
RX GND
LASER DRIVER
& SAFETY
CIRCUITRY
0.01 µF
VCC,R
0.01 µF
100
Rx_LOS
0.01 µF
AMPLIFICATION
&
QUANTIZATION
MOD_DEF2
GPIO(X)
GPIO(X)
GP14
MOD_DEF1
MOD_DEF0
REFCLK
4.7 K to
10 K
4.7 K to
10 K
4.7 K to
10 K
106.25 MHz
3.3 V
Figure 4. Recommended application configuration.
1 µH
VCCT
0.1 µF
1 µH
3.3 V
VCCR
0.1 µF
SFP MODULE
10 µF
0.1 µF
10 µF
HOST BOARD
NOTE: INDUCTORS MUST HAVE LESS THAN 1 Ω SERIES RESISTANCE PER MSA.
Figure 5. MSA required power supply filter.
6
0.01 µF
EEPROM
Table 2. Pin Description
Pin
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
Name
Vee T
Tx Fault
Tx Disable
MOD-DEF2
MOD-DEF1
MOD-DEF0
Rate Select
LOS
Vee R
Vee R
Vee R
RD–
RD+
Vee R
VCCR
VCCT
Vee T
TD+
TD–
Vee T
Function/Description
Transmitter Ground
Transmitter Fault Indication – High Indicates a Fault
Transmitter Disable – Module Disables on High or Open
Module Definition 2 – Two Wire Serial ID Interface
Module Definition 1 – Two Wire Serial ID Interface
Module Definition 0 – Grounded in Module
Not Connected
Loss of Signal – High Indicates Loss of Signal
Receiver Ground
Receiver Ground
Receiver Ground
Inverse Received Data Out
Received Data Out
Receiver Ground
Receiver Power – 3.3 V +/– 5%
Transmitter Power – 3.3 V +/– 5%
Transmitter Ground
Transmitter Data In
Inverse Transmitter Data In
Transmitter Ground
MSA Notes
Note 1
Note 2
Note 3
Note 3
Note 3
Note 4
Note 5
Note 5
Note 6
Note 6
Note 7
Note 7
Notes:
1. Tx Fault is an open collector/drain output which should be pulled up externally with a 4.7 K – 10 KΩ resistor on the host board to a supply
< VCC T+0.3 V or VCCR+0.3 V. When high, this output indicates a laser fault of some kind. Low indicates normal operation. In the low state, the
output will be pulled to < 0.8 V.
2. Tx disable input is used to shut down the laser output per the state table below. It is pulled up within the module with a 4.7 K – 10 KΩ resistor.
Low (0 – 0.8 V):
Transmitter On
Between (0.8 V and 2.0 V):
Undefined
High (2.0 – 3.465 V):
Transmitter Disabled
Open:
Transmitter Disabled
3. Mod-Def 0,1,2. are the module definition pins. They should be pulled up with a 4.7 K – 10 KΩ resistor on the host board to a supply less than
VCC T+0.3 V or VCC R+0.3 V.
Mod-Def 0 is grounded by the module to indicate that the module is present
Mod-Def 1 is clock line of two wire serial interface for optional serial ID
Mod-Def 2 is data line of two wire serial interface for optional serial ID
4. LOS (Loss of Signal) is an open collector/drain output which should be pulled up externally with a 4.7 K – 10 KΩ resistor on the host board to a
supply < V CCT, R+0.3 V. When high, this output indicates the received optical power is below the worst case receiver sensitivity (as defined by
the standard in use). Low indicates normal operation. In the low state, the output will be pulled to < 0.8 V.
5. RD–/+: These are the differential receiver outputs. They are AC coupled 100 Ω differential lines which should be terminated with 100 Ω
differential at the user SERDES. The AC coupling is done inside the module and is thus not required on the host board. The voltage swing on
these lines will be between 400 and 2400 mV differential (200 – 1200 mV single ended) when properly terminated.
6. VCC R and VCCT are the receiver and transmitter power supplies. They are defined as 3.135 – 3.465 V at the SFP connector pin. The maximum
supply current is 200 mA and the associated in-rush current will typically be no more than 30 mA above steady state after 500 nanoseconds.
7. TD–/+: These are the differential transmitter inputs. They are AC coupled differential lines with 100 Ω differential termination inside the module.
The AC coupling is done inside the module and is thus not required on the host board. The inputs will accept differential swings of 500 – 2400 mV
(250 – 1200 mV single ended), though it is recommended that values between 500 and 1200 mV differential (250 – 600 mV single ended) be used
for best EMI performance. These levels are compatible with CML and LVPECL voltage swings.
7
Table 3. Absolute Maximum Ratings
Parameter
Storage Temperature
Case Temperature
Relative Humidity
Module Supply Voltage
Data/Control Input Voltage
Sense Output Current – LOS, Tx Fault
MOD-DEF 2
Symbol
TS
TC
RH
VCCT,R
VI
ID
ID
Minimum
–40
0
5
–0.5
–0.5
Typical
Maximum
100
85
95
3.6
VCC+0.3
150
5.0
Unit
°C
°C
%
V
V
mA
mA
Notes
Note 1
Note 1, 2
Note 1
Note 1
Note 1
Note 1
Note 1
Notes:
1. Absolute Maximum Ratings are those values beyond which damage to the device may occur if these limits are exceeded for other than a short
period of time. See Reliability Data Sheet for specific reliability performance.
2. Between Absolute Maximum Ratings and the Recommended Operating Conditions functional performance is not intended, device reliability is
not implied, and damage to the device may occur over an extended period of time.
Table 4. Recommended Operating Conditions
Parameter
Case Temperature
Module Supply Voltage
Data Rate
Symbol
TC
VCCT,R
Minimum
0
3.135
Typical
3.3
1.0625
2.125
Maximum
70
3.465
Unit
°C
V
Gb/s
Notes
Note 1
Note 1
Note 1
Note:
1. Recommended Operating Conditions are those values outside of which functional performance is not intended, device reliability is not implied,
and damage to the device may occur over an extended period of time. See Reliability Data Sheet for specific reliability performance.
Table 5. Transceiver Electrical Characteristics (TC = 0°C to 70°C, VCCT,R = 3.3 V ± 5%)
Parameter
Symbol
AC Electrical Characteristics
Power Supply Noise
PSNR
Rejection (peak-to-peak)
DC Electrical Characteristics
Module Supply Current ICC
Power Dissipation
PDISS
Sense Outputs:
Transmit Fault
VOH
(TX_FAULT),
Loss of Signal (LOS),
VOL
MOD-DEF 2
Control Inputs:
Transmitter Disable
VIH
(TX_DISABLE)
MOD-DEF 1,2
VIL
Minimum
Typical
100
133
440
Unit
Notes
mV
Note 1
200
693
mA
mW
VCCT, R+0.3
V
0.8
V
2.0
VCCT,R
V
0
0.8
V
2.0
Notes:
1. MSA filter is required on host board 10 Hz to 2 MHz.
2. LVTTL, external 4.7 – 10 KΩ pull-up resistor required.
3. LVTTL, external 4.7 – 10 KΩ resistor required for MOD-DEF 1 and MOD-DEF 2.
8
Maximum
Note 2
Note 3
Table 6. Transmitter and Receiver Electrical Characteristics (TC = 0°C to 70°C, VCCT,R = 3.3 V ± 5%)
Parameter
Data Input:
Transmitter Differential
Input Voltage (TD +/–)
Data Output:
Receiver Differential
Output Voltage (RD +/–)
Contributed Deterministic
Jitter (Receiver) 2.125 Gb/s
Contributed Deterministic
Jitter (Receiver) 1.0625 Gb/s
Contributed Random
Jitter (Receiver) 2.125 Gb/s
Contributed Random
Jitter (Receiver) 1.0625 Gb/s
Receive Data Rise and
Fall Times (Receiver)
Symbol
Minimum
V1
400
VO
400
DJ
DJ
RJ
RJ
Trf
Typical
735
Maximum
Unit
Notes
2400
mV
Note 1
2000
mV
Note 2
0.1
47
0.12
113
0.162
76
0.098
92
250
UI
ps
UI
ps
UI
ps
UI
ps
ps
Note 3, 6
Note 3, 6
Note 4, 6
Note 4, 6
Note 5
Notes:
1. Internally AC coupled and terminated (100 Ohm differential). These levels are compatible with CML and LVPECL voltage swings.
2. Internally AC coupled with an external 100 Ohm differential load termination.
3. Contributed DJ is measured on an oscilloscope in average mode with 50% threshold and K28.5 pattern.
4. Contributed RJ is calculated for 1 x 10–12 BER by multiplying the RMS jitter (measured on a single rise or fall edge) from the oscilloscope by 14.
Per the FC-PI standard (Table 13 – MM Jitter Output, note 1), the actual contributed RJ is allowed to increase above its limit if the actual
contributed DJ decreases below its limits, as long as the component output DJ and TJ remain within their specified FC-PI maximum limits with
the worst case specified component jitter input.
5. 20%–80% Rise and Fall times measured with a 500 MHz signal utilizing a 1010 data pattern.
6. In a network link, each component‘s output jitter equals each component‘s input jitter combined with each component‘s contributed jitter.
Contributed DJ adds in a linear fashion and contributed RJ adds in a RMS fashion. In the Fibre Channel FC-PI Rev 11 specification ”6.3.3 MM
Jitter Budget“ section, there is a table specifying the input and output DJ and TJ for the receiver at each data rate. In that table, RJ is found from
TJ - DJ where the Rx input jitter is noted as Gamma R and the Rx output jitter is noted as Delta R. Our component contributed jitter is such that, if
the maximum specified input jitter is present, and is combined with our maximum contributed jitter, then we meet the specified maximum output
jitter in the FC-PI MM jitter specification table.
9
Table 7. Transmitter Optical Characteristics (TC = 0°C to 70°C, VCCT,R = 3.3 V ± 5%)
Parameter
Output Optical Power
(Average)
Symbol
Pout
Minimum
–10
Typical
–6.3
Maximum
–1.5
Unit
dBm
Pout
–10
–6.2
–1.5
dBm
Optical Extinction Ratio
Optical Modulation
Amplitude (Peak-to-Peak)
2.125 Gb/s
Optical Modulation
Amplitude (Peak-to-Peak)
1.0625 Gb/s
Center Wavelength
Spectral Width – rms
Optical Rise/Fall Time
ER
OMA
196
9
392
dB
µW
OMA
156
350
µW
FC-PI Std
Note 2
λC
σ
Trise/fall
830
860
0.85
150
nm
nm
ps
RIN12 (OMA), maximum
Contributed Deterministic
Jitter (Transmitter) 2.125 Gb/s
Contributed Deterministic
Jitter (Transmitter) 1.0625 Gb/s
Contributed Random
Jitter (Transmitter) 2.125 Gb/s
Contributed Random
Jitter (Transmitter) 1.0625 Gb/s
Pout TX_DISABLE Asserted
RIN
DJ
–117
0.12
56
0.09
85
0.134
63
0.177
167
–35
dB/Hz
UI
ps
UI
ps
UI
ps
UI
ps
dBm
FC-PI Std
FC-PI Std
20% – 80%,
FC-PI Std
FC-PI Std
Note 3, 5
DJ
RJ
RJ
POFF
Notes
50/125 um,
NA = 0.2
62.5/125 um,
NA = 0.275
FC-PI Std
Note 1
Note 3, 5
Note 4, 5
Note 4, 5
Notes:
1. An OMA of 196 is approximately equal to an average power of –9 dBm assuming an Extinction Ratio of 9 dB.
2. An OMA of 156 is approximately equal to an average power of –10 dBm assuming an Extinction Ratio of 9 dB.
3. Contributed DJ is measured on an oscilloscope in average mode with 50% threshold and K28.5 pattern.
4. Contributed RJ is calculated for 1 x 10–12 BER by multiplying the RMS jitter (measured on a single rise or fall edge) from the oscilloscope by 14.
Per the FC-PI standard (Table 13 – MM Jitter Output, note 1), the actual contributed RJ is allowed to increase above its limit if the actual
contributed DJ decreases below its limits, as long as the component output DJ and TJ remain within their specified FC-PI maximum limits with
the worst case specified component jitter input.
5. In a network link, each component‘s output jitter equals each component‘s input jitter combined with each component‘s contributed jitter.
Contributed DJ adds in a linear fashion and contributed RJ adds in a RMS fashion. In the Fibre Channel FC-PI Rev 11 specification ”6.3.3 MM
Jitter Budget“ section, there is a table specifying the input and output DJ and TJ for the receiver at each data rate. In that table, RJ is found from
TJ - DJ where the Rx input jitter is noted as Gamma R and the Rx output jitter is noted as Delta R. Our component contributed jitter is such that, if
the maximum specified input jitter is present, and is combined with our maximum contributed jitter, then we meet the specified maximum output
jitter in the FC-PI MM jitter specification table.
10
Table 8. Receiver Optical Characteristics (TC = 0°C to 70°C, VCCT,R = 3.3 V ± 5%)
Parameter
Optical Power
Min. Optical Modulation
Amplitude (Peak-to-Peak) 2.125 Gb/s
Min. Optical Modulation
Amplitude (Peak-to-Peak) 1.0625 Gb/s
Stressed Receiver
Sensitivity (OMA)
2.125 Gb/s
Symbol
PIN
OMA
Minimum
Typical
49
16
Unit
dBm
µW
OMA
31
18
µW
96
33
µW
109
25
µW
Stressed Receiver
Sensitivity (OMA)
1.0625 Gb/s
55
19
µW
67
16
µW
Return Loss
Loss of Signal – Assert
Loss of Signal – De-Assert
Loss of Signal Hysteresis
12
–31
2.3
dB
dBm
dBm
dB
PA
PD
PD–P A
0.5
Maximum
0
–17.5
–17.0
5
Notes
FC-PI Std
FC-PI Std
Note 1
FC-PI Std
Note 2
50 µm fiber,
FC-PI Std
62.5 µm fiber,
FC-PI Std
Note 3
50 µm fiber,
FC-PI Std
62.5 µm fiber,
FC-PI Std
Note 4
FC-PI Std
Note 5
Note 5
Notes:
1. An OMA of 49 µW is approximately equal to an average power of –15 dBm, and the OMA typical of 16 µW is approximately equal to an average
power of –20 dBm, assuming an Extinction Ratio of 9 dB. Sensitivity measurements are made at eye center with a BER = 10E–12.
2. An OMA of 31 is approximately equal to an average power of –17 dBm assuming an Extinction Ratio of 9 dB.
3. 2.125 Gb/s Stressed receiver vertical eye closure penalty (ISI) min. is 1.26 dB for 50 µm fiber and 2.03 dB for 62.5 µm fiber. Stressed receiver DCD
component min. (at TX) is 40 ps.
4. 1.0625 Gb/s Stressed receiver vertical eye closure penalty (ISI) min. is 0.96 dB for 50 µm fiber and 2.18 dB for 62.5 µm fiber. Stressed receiver
DCD component min. (at TX) is 80 ps.
5. These average power values are specified with an Extinction Ratio of 9 dB. The loss of Signal circuitry responds to OMA (peak to peak) power,
not to average power.
Table 9. Transceiver Timing Characteristics (TC = 0°C to 70°C, VCCT,R = 3.3 V ± 5%)
Parameter
Tx Disable Assert Time
Tx Disable Negate Time
Time to Initialize,
Including Reset of Tx_Fault
Tx Fault Assert Time
Tx Disable to Reset
LOS Assert Time
LOS Deassert Time
Serial ID Clock Rate
Symbol
t_off
t_on
t_init
t_fault
t_reset
t_loss_on
t_loss_off
f-serial-clock
Minimum
Maximum
10
1
300
Unit
µs
ms
ms
Notes
Note 1
Note 2
Note 3
100
µs
µs
µs
µs
kHz
Note 4
Note 5
Note 6
Note 7
10
100
100
100
Notes:
1. Time from rising edge of Tx Disable to when the optical output falls below 10% of nominal.
2. Time from falling edge of Tx Disable to when the modulated optical output rises above 90% of nominal.
3. From power on or negation of Tx Fault using Tx Disable.
4. Time from fault to Tx fault on.
5. Time Tx Disable must be held high to reset Tx_Fault.
6. Time from LOS transition to Rx LOS assert per Figure 6.
7. Time from non-LOS transition to Rx LOS deassert per Figure 6.
11
VCC > 3.15 V
VCC > 3.15 V
Tx_FAULT
Tx_FAULT
Tx_DISABLE
Tx_DISABLE
TRANSMITTED SIGNAL
TRANSMITTED SIGNAL
t_init
t_init
t-init: TX DISABLE NEGATED
t-init: TX DISABLE ASSERTED
VCC > 3.15 V
Tx_FAULT
Tx_FAULT
Tx_DISABLE
Tx_DISABLE
TRANSMITTED SIGNAL
TRANSMITTED SIGNAL
t_off
t_on
t_init
INSERTION
t-init: TX DISABLE NEGATED, MODULE HOT PLUGGED
t-off & t-on: TX DISABLE ASSERTED THEN NEGATED
OCCURANCE OF FAULT
OCCURANCE OF FAULT
Tx_FAULT
Tx_FAULT
Tx_DISABLE
Tx_DISABLE
TRANSMITTED SIGNAL
TRANSMITTED SIGNAL
t_reset
t_fault
t-fault: TX FAULT ASSERTED, TX SIGNAL NOT RECOVERED
t_init*
t-reset: TX DISABLE ASSERTED THEN NEGATED, TX SIGNAL RECOVERED
OCCURANCE OF FAULT
Tx_FAULT
LOS
TRANSMITTED SIGNAL
t_fault
t_reset
* SFP SHALL CLEAR Tx_FAULT IN
t_init IF THE FAILURE IS TRANSIENT
t_loss_on
t_init*
t-fault: TX DISABLE ASSERTED THEN NEGATED,
TX SIGNAL NOT RECOVERED
Figure 6. Transceiver timing diagrams (module installed except where noted).
12
OCCURANCE
OF LOSS
OPTICAL SIGNAL
Tx_DISABLE
t-loss-on & t-loss-off
t_loss_off
Table 10. EEPROM Serial ID Memory Contents
Address
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
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
Hex
03
04
07
00
00
00
00
20
40
0C
05
01
15
00
00
00
1E
0F
00
00
41
47
49
4C
45
4E
54
20
20
20
20
20
20
20
20
20
00
00
30
D3
ASCII
A
G
I
L
E
N
T
Address
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
Hex
48
46
42
52
2D
35
37
32
30
4C
20
20
20
20
20
20
20
20
20
20
00
00
00
Note 3
00
1A
00
00
ASCII
H
F
B
R
–
5
7
2
0
L
Address
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
Hex
Note 1
Note 1
Note 1
Note 1
Note 1
Note 1
Note 1
Note 1
Note 1
Note 1
Note 1
Note 1
Note 1
Note 1
Note 1
Note 1
Note 2
Note 2
Note 2
Note 2
Note 2
Note 2
Note 2
Note 2
00
00
00
Note 3
ASCII
Address
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
Hex
Notes:
1. Address 61–83 specify a unique identifier.
2. Address 84–91 specify the date code.
3. Addresses 63 and 95 are check sums. Address 63 is the check sum for bytes 0–62 and address 95 is the check sum for bytes 64–94.
13
ASCII
AGILENT HFBR-5720L
850 nm LASER PROD
21CFR(J) CLASS 1
COUNTRY OF ORIGIN YYWW
XXXXXX
13.40 ± 0.1
(0.53 ± 0.004)
13.75 ± 0.1
(0.54 ± 0.004)
56.40 ± 0.2
(2.22 ± 0.01)
SEE DETAIL 1
TCASE REFERENCE POINT
AREA
FOR
PROCESS
PLUG
14.8 MAX. UNCOMPRESSED
(0.58)
13.0 ± 0.1
(0.51 ± 0.004)
14.20 ± 0.1
(0.56 ± 0.004)
DETAIL 1
SCALE 2x
0.7 MAX. UNCOMPRESSED
(0.03)
8.50 ± 0.1
(0.33 ± 0.004)
6.25 ± 0.05
(0.25 ± 0.002)
11.80 ± 0.2
(0.46 ± 0.008)
DIMENSIONS ARE IN MILLIMETERS (INCHES)
Figure 7a. Module drawing.
14
FRONT EDGE OF SFP
TRANSCEIVER CAGE
TX
RX
X
Y
34.5
10
3x
10x ∅1.05 ± 0.01
∅ 0.1 L X A S
16.25
MIN. PITCH
7.2
7.1
1
2.5
B
PCB
EDGE
∅ 0.85 ± 0.05
∅ 0.1 S X Y
A
1
2.5
3.68
5.68
20
PIN 1
8.58
11.08
16.25
REF. 14.25
2x 1.7
8.48
9.6
4.8
11
10
11.93
SEE DETAIL 1
2.0
11x
11x 2.0
9x 0.95 ± 0.05
∅ 0.1 L X A S
5
26.8
10
3x
3
2
41.3
42.3
5
3.2
0.9
LEGEND
20
PIN 1
10.53
10.93
9.6
20x 0.5 ± 0.03
0.06 L A S B S
11.93
0.8
TYP.
1.PADS AND VIAS ARE CHASSIS GROUND
2.THROUGH HOLES, PLATING OPTIONAL
11
10
3.HATCHED AREA DENOTES COMPONENT
AND TRACE KEEPOUT (EXCEPT
CHASSIS GROUND)
4
2x 1.55 ± 0.05
∅ 0.1 L A S B S
DETAIL 1
Figure 7b. SFP host board mechanical layout.
15
2 ± 0.005 TYP.
0.06 L A S B S
4.AREA DENOTES COMPONENT
KEEPOUT (TRACES ALLOWED)
DIMENSIONS ARE IN MILLIMETERS
1.7 ± 0.9
(0.07 ± 0.04)
3.5 ± 0.3
(0.14 ± 0.01)
PCB
41.73 ± 0.5
(1.64 ± 0.02)
BEZEL
15 MAX.
(0.59)
AREA
FOR
PROCESS
PLUG
CAGE ASSEMBLY
15.25 ± 0.1
(0.60 ± 0.004)
11 REF.
(0.43)
10.4 ± 0.1
(0.41 ± 0.004)
9.8
MAX.
(0.39)
1.5 REF.
(0.06)
BELOW PCB
10 REF
(0.39)
TO PCB
0.4 ± 0.1
(0.02 ± 0.004)
BELOW PCB
16.25 ± 0.1 MIN. PITCH
(0.64 ± 0.004)
MSA-SPECIFIED BEZEL
DIMENSIONS ARE IN MILLIMETERS (INCHES).
Figure 7c. Assembly drawing.
www.semiconductor.agilent.com
Data subject to change.
Copyright © 2001 Agilent Technologies, Inc.
August 20, 2001
Obsoletes 5988-0967EN
5988-3490EN
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