AVAGO AFBR

AFBR-720XPDZ
10GbE XFP 850 nm 10Gbps Optical Transceiver
Data Sheet
Description
Features
The 850 nm XFP transceiver is a high performance, cost effective module for serial optical data communications
applications specified for signal rates of 9.9 Gb/s to 10.5
Gb/s. It is compliant to XFP MSA Rev 4.5. The module is
designed for multi mode fiber and operates at a nominal
wavelength of 850 nm. The transmitter section incorporates Avago Technologies’ 850 nm Vertical Cavity Surface
Emitting Laser (VCSEL). The receiver section uses Avago
Technologies’ MOVPE grown planar SEDET PIN photodetector for low dark current and excellent responsivity.
Integrated Tx and Rx signal conditioners provide high
jitter-tolerance for full XFI compliance. The internally ac
coupled high speed serial I/O simplifies interfacing to
external circuitry. The electrical interface is made using
an industry standard 0.8 mm pitch 30-pin right angle
connector. Optical connection is made via the duplex LC
connector.
• RoHS 6/6 Compliance
• ����������
Compliant to XFP MSA
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• Compliant to IEEE 802.3ae 10GBASE-SR for 10GbE,
10.3125 Gb/s
• Compliant XFI 10G Serial electrical interface
• 3.3V single power supply
• Avago Technologies’ 850 nm VCSEL Laser and PIN
Photodiode
• No reference clock required
• LC Duplex optical connector interface conforming to
ANSI TIA/EIA604-10 (FOCIS 10)
• 1.5W maximum
• Link Lengths up to 300 m with 0M3 fiber
• 0 to +70 °C case operating temperature range
• Superior Thermal and EMI integrity performance to support high port densities
• Customizable clip-on heatsink to support a variety of
line card environments
• IEC 60825-1 Class 1/CDRH Class 1 laser eye safety
The product also offers digital diagnostics using the 2wire serial interface defined in the XFP MSA. The product provides real time temperature (module and laser), supply voltage, laser bias current, laser average output power
and received input power. The digital diagnostic interface
also adds the ability to disable the transmitter (TX_DIS),
power down the module, monitor for module faults and
monitor for Receiver Loss of Signal (RX_LOS). Transmitter
disable, interrupt, power down/reset, receiver loss of signal and module not ready are also hard wired pins on the
30-pin right angle connector.
Applications
•
•
•
•
•
Fiber Channel Switches
Host Bus Adapter Cards
Mass Storage System and Server I/O
Ethernet Switches
Core Routers
Installation
The AFBR-720XPDZ can be installed in any XFP port regardless of host equipment operating status. The AFBR720XPDZ is hot-pluggable, allowing the module to be
installed while the host system is operating and on-line.
Upon insertion, the transceiver housing makes initial
contact with the host board XFP cage, mitigating potential damage due to Electro-Static Discharge (ESD). Once
fully inserted into the XFP cage, the top surface of the
XFP module makes contact with the heatsink through a
cutout in the top of the cage ensuring an effective thermal path for module heat.
Functional Description
Transmitter Section
The transmitter section includes a 850 nm VCSEL (Vertical
Cavity Surface Emitting Laser) light source, a transmitter driver circuit and a signal conditioner circuit on the
TX data inputs. (see Figure 1) Optical connection to the
transmitter is provided via a LC connector. The optical
output is controlled by an IC that detects the laser output via the monitor photodiode. This IC provides both dc and
ac current drive to the laser to ensure correct modulation,
eye diagram and extinction ratio over temperature, supply voltage and operating life.
TX_DIS
Asserting pin 5, TX_DIS, will disable the transmitter optical output. The transmitter output can also be disabled
and monitored via the two-wire serial interface.
Eye Safety Circuit
Under normal operating conditions laser power will be
maintained below Class 1 eye-safety limits. Should a
catastrophic laser fault occur and optical power become
uncontrolled, the micro-controller and laser driver IC
will detect the fault, shut down the laser, power down
the module and assert the hard-wired MOD_NR flag. The
TX_FAULT output in the 2-wire serial interface will also be
asserted.
Heat sink
Analog bus
RF
driver
Mon. PIN
Conditioner
CW
driver
conditioners
Analog
signal
Optical receptacles
TOSA
EEPROM
Micro
controller
A/D
Power
supply
control
PIN
Digital 10
Gb/s electrical
I/O
Digital low
speed bus or
signal
Analog signal
TIA
ROSA
Signal
Conditioner
Main housing
Figure 1. Transceiver Functional Diagram
Electrical connector
Laser
+3.3V
Signal
ESA
Receiver Section
Functional Data I/O
The receiver section includes a PIN detector with amplification quantization signal conditioner circuits. (see
Figure 1) Optical connection to the receiver is provided
via a LC optical connector.
Avago Technologies’ AFBR-720XPDZ fiber-optic transceiver is designed to accept industry standard electrical
input differential signals. The transceiver provides accoupled, internally terminated data input and output interfaces. Bias resistors and coupling capacitors have
been included within the module to reduce the number
of components required on the customer’s board.
RX_LOS
The receiver section contains a loss of signal (RX_LOS)
circuit to indicate when the optical input signal power
is insufficient for reliable signal detection. A high signal
indicates loss of modulated signal, indicating link failure
such as a broken fiber or nonfunctional remote transmitter. RX_LOS can also be monitored via the two-wire
serial interface (byte 110, bit 1).
Electrical Pinout
GND
RX_LOS
14
17
RD-
MOD_NR
13
18
RD+
MOD_ABS
12
19
GND
SDA
11
VCC5
20
VCC2
SCL
10
0.1 µF
Host +3.3 V
0.1 µF
Optional
Host +1.8 V
22 µF
0.1 µF
21
P_DOWN/RST
VCC3
9
4.7 µH
22
VCC2
VCC3
8
22 µF
23
GND
GND
7
4.7 µH
24
REFCLK+
VCC5
6
25
REFCLK-
TX_DIS
5
0.1 µF
Optional
Host -5.2 V
22 µF
26
GND
4.7 µH
27
GND
MOD_DESEL
3
0.1 µF
22 µF
28
TD-
VEE5
2
29
TD+
GND
1
30
GND
VCC3
0.1 µF
VCC2
XFP Connector
4.7 µH
0.1 µF
VEE5
0.1 µF
TOWARD
ASIC
XFP Module
GND
Figure 2. MSA recommended power supply filter
15
16
Host Board
Optional
Host +5 V
GND
Figure 3. Host PCB XFP Pinout Top View
INTERRUPT
4
TOWARD
BEZEL
Table 1. Electrical Pin Definitions
Pin
Name
Logic
Function/Description
Notes
1
GND
Module Ground
1
2
VEE5
3
Mod-Desel
LVTTL-I
Module De-select; When held low allows the module to respond to 2wire Serial interface commands
4
Interrupt
LVTTL-O
Interrupt; Indicates presence of an important condition which can be
readover the serial 2-wire interface
5
TX_DIS
LVTTL-I
Transmitter Disable; Transmitter Laser Source Turned Off
6
VCC5
5 V power supply. Not internally connected.
7
GND
Module Ground
8
VCC3
+3.3 V Power Supply
9
VCC3
+3.3 V Power Supply
10
SCL
LVTTL-I
Two Wire Interface Clock
2
11
SDA
LVTTL-I/O
Two Wire Interface Data Line
2
12
Mod_Abs
LVTTL-O
LVTTL-O Mod_Abs Indicates Module is not present. Grounded in the
Module
2
13
Mod_NR
LVTTL-O
Module Not Ready; Indicating Module Operational Fault
2
14
RX_LOS
LVTTL-O
Receiver Loss Of Signal Indicator
2
15
GND
Module Ground
1
16
GND
Module Ground
1
17
RD-
CML-O
Receiver Inverted Data Output
18
RD+
CML-O
Receiver Non-Inverted Data Output
19
GND
Module Ground
20
VCC2
+1.8 V Power Supply. Not internally connected.
21
P_Down/RST
22
VCC2
+1.8 V Power Supply. Not internally connected.
23
GND
Module Ground
1
24
RefCLK+
PECL-I
Reference Clock Non-Inverted Input, ac coupled on the host board (Not Used)
3
25
RefCLK-
PECL-I
Reference Clock Inverted Input, ac coupled on the host board (Not Used) 3
26
GND
27
GND
28
TD-
CML-I
Transmitter Inverted Data Input
29
TD+
CML-I
Transmitter Non-Inverted Data Input
30
GND
-5.2 V power supply. Not internally connected.
LVTTL-I
1
1
Power down: When high, the module is put into a lower power mode.
Serial interface is functional in the low power mode. Reset: The falling
edge initiates a complete reset of the module including the serial Interface, equivalent to a power cycle.
Module Ground
1
Module Ground
1
Module Ground
Notes:
1. Module ground pins Gnd are isolated from the module case and chassis ground within the module.
2. Open Collector should be pulled up with 4.7 K-10 Kohms to a voltage between 3.15 V and 3.6 V on the host board.
3. RefCLK+/- are internally terminated (50Ω)
2
1
Absolute Maximum Ratings
Parameter
Symbol
Minimum
Storage Temperature (non-operating)
TS
Relative Humidity
Typical
Maximum
Unit
Notes
-40
+85
°C
1, 2
RH
10
90
%
1
Supply Voltage
VCC3
0
3.6
V
1, 2
Low Speed Input Voltage
VIN
-0.5
VCC+0.5
V
1
Recommended Operating Conditions [4]
Parameter
Symbol
Minimum
Case Operating Temperature
TC
Supply Voltage
VCC3
Maximum
Unit
Notes
0
+70
°C
3
3.135
3.465
V
5
Data Rate
Typical
10.3125
Gb/s
Transceiver Electrical Characteristics
(TC = 0 °C to +70 °C, VCC3 = 3.3 V ± 5%)
Parameter
Symbol
Maximum
Unit
Notes
Power Supply Noise Rejection
(peak-peak) under 1MHz
PSNR
Minimum
Typical
2% of VCC
mV
6
Power Supply Noise Rejection
(peak-peak) 1MHz to 10 MHz
PSNR
3% of VCC
mV
6
Module supply current
ICC
430
mA
Power Dissipation
PDISS
1
1.5
W
Low Speed Outputs:
MOD_NR, RX_LOS, MOD_ABS,
INTERRUPT
VOH
VOL
Host_VCC-0.5
0.0
0.01
Host_VCC+0.3
0.4
V
V
7
8
Low Speed Inputs:
TX_DIS, MOD_DESEL,
P_DOWN/RST
VIH
VIL
2.0
-0.3
VCC3+0.3
0.8
V
V
10
9
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.
3. The Ambient Operating Temperature limitations are based on the Case Operating Temperature limitations and are subject to the host system
thermal design.
4. Recommended Operating Conditions are those values for which functional performance and device reliability is implied
5. Vcc condition applies to supply voltage at the XFP module
6. Filter per XFP specification is required on the host board.
7. 4.7 kW to 10 kW resistor pull-up to host_VCC, measured at the host side of connector. IOH(max) = - 2 mA.
8. 4.7 kW to 10 kW resistor pull-up to host_VCC, measured at the host side of connector. IOL(max) = 2 mA.
9. 4.7 kW to 10 kW resistor pull-up to host_VCC, measured at the host side of connector. IIL(max) = 10 µA.
10.4.7 kW to 10 kW resistor pull-up to host_VCC, measured at the host side of connector. IIH(max) = - 10 µA.
Transmitter Electrical Input Characteristics
(TC = 0 °C to +70 °C, VCC3 = 3.3 V ± 5%)
Parameter
Symbol
Minimum
Differential Input Impedance
Zd
Termination Mismatch
DZM
Differential Input Amplitude
DVQDO
120
Differential Input Return Loss
SDD11
Differential Input Return Loss
Typical
Maximum
Unit
Notes
W
100
5
%
820
mV
peak to peak (1)
20
dB
0.05 to 0.1 GHz
SDD11
8
dB
0.1 to 5.5 GHz
Differential Input Return Loss
SDD11
8 - 20.66
log10(f/5.5)
f in GHz
dB
5.5 - 12 GHz
Common Mode Input Return
Loss
SCC11
3
dB
0.1 to 15 GHz
Differential to Common Mode
Conversion
SCD11
10
dB
0.1 to 15 GHz
Jitter and Eye Mask
XFP MSA Compliant
Receiver Electrical Output Characteristics
Parameter
Symbol
Differential Input Impedance
Zd
Termination Mismatch
DZM
Differential Output Amplitude
DC Common Mode Potential
Vcm
Minimum
Typical
Maximum
Unit
W
100
5
%
340
850
mV
0
3.6
V
15
mV
Output AC Common Mode Voltage
Notes
peak to peak (1)
RMS
Output Rise/Fall time (20% to 80%)
tRH, tFH
24
Common mode output return
loss
SCC22
3
Differential output return loss
SDD22
20
dB
0.05 to 0.1 GHz
Differential output return loss
SDD22
8
dB
0.1 to 5.5 GHz
Differential output return loss
SDD22
8 - 20.66
log10(f/5.5)
f in GHz
dB
5.5 - 12 GHz
Jitter and Eye Mask
Note:
1. The differential input and output amplitudes are per XFP MSA mask at points B’ and C’.
ps
0.1 to 15 GHz
XFP MSA Compliant
Transmitter Optical Characteristics 10 GbE
(TC = 0 °C to +70 °C, VCC3 = 3.3 V ± 5%)
Parameter
Symbol
Minimum
Laser OMA Output Power
Pout
-4.3
Mean Optical Output Power
Pout
-7.3
Extinction Ratio
ER
3.0
Spectral Width - rms
s, rms
Center Wavelength
λC
Transmitter and dispersion penalty
Typical
Maximum
Unit
Notes
dBm
1, 2, 4
dBm
1, 2, 3, 5
dB
1, 2
0.45
nm RMS
4
860
nm
TDP
3.9
dB
Transmitter OFF Average Optical
Output Power
Poff
-30
dBm
RIN12 (OMA)
RIN
-128
dB/Hz
Optical Eye Mask
Compliant with IEEE 802.3ae 10GBASE-SR XFP MSA
-1
840
850
1, 2
1
See Fig 4
Receiver Optical Characteristics 10 GbE
(TC = 0 °C to +70 °C, VCC3 = 3.3 V ± 5%)
Parameter
Symbol
Minimum
Typical
Stressed receiver sensitivity (OMA)
Receiver sensitivity (OMA)
PIN
Receiver Reflectance
Wavelength
λC
840
850
Maximum
Unit
Notes
-7.5
dBm
1
-11.1
dBm
3
-12
dB
1
860
nm
Notes:
1. 10GFC 1200-MX-SN-I / IEEE 802.3ae 10GBASE-SR compliant
2. These parameters are interrelated: see IEEE 802.3ae, Clause 52.
3. For information only
4. Trade-offs are available between spectral width, center wavelength and minimum Optical Modulation Amplitude (OMA). See Figure 4A and
Optical Modulation Table.
5. The maximum 10GBASE-SR Average Optical Output Power shall be the lesser of the class 1 safety limit as defined by IEEE 802.3ae 52.10.2 or
the average receive power maximum defined by IEEE 802.3ae Table 52-9
Note: where X1, X2, X3, Y1, Y2, Y3 = 0.25, 0.40, 0.45, 0.25, 0.28, 0.40 respectively
Figure 4. Transmitter Eye Mask Definition
Minimum transmit OMA (dBm)
-2.5
-2.7
-2.9
-3.1
-3.3
-3.5
-3.7
-3.9
-4.1
-4.3
-4.5
840
0.4 to 0.45 nm
0.35 to 0.4 nm
0.3 to 0.35 nm
0.25 to 0.3 nm
0.2 to 0.25 nm
0.15 to 0.2 nm
Up to 0.05 nm
845
850
855
Center wavelength (nm)
860
Figure 4a. Triple tradeoff curve for 10GBASE-S (informative)
Optical Modulation
RMS Spectral width (nm)
Up to
0.05
0.05 to
0.1
0.1 to
0.15
0.15 to
0.2
0.2 to
0.25
0.25 to
0.3
0.3 to
0.35
0.35 to
0.4
0.4 to
0.45
840 to 842
-4.2
-4.2
-4.1
-4.1
-3.9
-3.8
-3.5
-3.2
-2.8
842 to 844
-4.2
-4.2
-4.2
-4.1
-3.9
-3.8
-3.6
-3.3
-2.9
844 to 846
-4.2
-4.2
-4.2
-4.1
-4.0
-3.8
-3.6
-3.3
-2.9
846 to 848
-4.3
-4.2
-4.2
-4.1
-4.0
-3.8
-3.6
-3.3
-2.9
848 to 850
-4.3
-4.2
-4.2
-4.1
-4.0
-3.8
-3.6
-3.3
-3.0
850 to 852
-4.3
-4.2
-4.2
-4.1
-4.0
-3.8
-3.6
-3.4
-3.0
852 to 854
-4.3
-4.2
-4.2
-4.1
-4.0
-3.9
-3.7
-3.4
-3.1
854 to 856
-4.3
-4.3
-4.2
-4.1
-4.0
-3.9
-3.7
-3.4
-3.1
856 to 858
-4.3
-4.3
-4.2
-4.1
-4.0
-3.9
-3.7
-3.5
-3.1
858 to 860
-4.3
-4.3
-4.2
-4.2
-4.1
-3.9
-3.7
-3.5
-3.2
CenterWavelength(nm)
Transceiver Timing Characteristics
(TC = 0 °C to +70 °C, VCC3 = 3.3 V ± 5%)
Parameter
Symbol
TX_DIS Assert Time
Minimum
Maximum
Unit
Notes
t_off
10
µs
Time from rising edge of TX_DIS
to when the optical output falls
below 10% of nominal.
TX_DIS Negate Time
t_on
2
ms
Time from falling edge of TX_DIS
to when the modulated optical
output rises above 90% of nominal.
Time to initialize
t_init
300
ms
From power on or hot plug after
meeting power supply specs
Interrupt assert delay
Interrupt_on
200
ms
From occurrence of the condition
triggering interrupt
Interrupt negate
delay
Interrupt_off
500
us
From clear on read interrupt flags
P_Down/
RST assert delay
P_Down/RST_on
100
us
From Power down initiation
P-Down negate delay
P_Down/RST_off
300
ms
Max delay from negate to completion of power up and reset
Mod_NR assert delay
Mod_nr_on
1
ms
From Occurrence of fault to assertion of Mod_NR
Mod_NR negate
delay
Mod_nr_off
1
ms
From Occurrence of signal to negation of Mod_NR
Mod_DeSel assert time
T_Mod_DeSel
2
ms
Maximum delay between assertion
of Mod_DeSel and end of module
response to 2-wire interface communications
2
ms
Maximum delay between de-assertion of Mod_DeSel and proper
module response to 2-wire interface communications
µs
Min length of P-Down assert to
initial reset
100
µs
From Occurrence of loss of signal
to assertion of RX_LOS
From Occurrence of presence of
signal to negation of RX_LOS
Mod_DeSel de-assert T_Mod_Sel
time
Typical
P_Down reset time
t_reset
RX_LOS Assert delay
T_loss_on
RX_LOS negate delay
T_loss_off
2.3
100
µs
Serial ID Clock Rate
f_serial_clock
0
400
kHz
10
Host Board
Clip
Heat Sink
Cage Assembly
Connector
EMI Gasket
(not shown)
Case Temperature
Measurement Point
•
Bezel
Module
Figure 5. XFP Assembly Drawing
10
Digital Diagnostic Interface and Serial Identification
Transceiver Internal Temperature
The 2-wire serial interface is explicitly defined in the XFP MSA Rev 4.0. 2-wire timing specifications and the structure of the memory map are per XFP MSA Rev 2.0. The
normal 256 Byte I2C address space is divided into lower
and upper blocks of 128 Bytes. The lower block of 128
Bytes is always directly available and is used for diagnostic information providing the opportunity for Predictive
Failure Identification, Compliance Prediction, Fault Isolation and Component Monitoring. The upper address
space tables are used for less frequently accessed functions such as serial ID, user writeable EEPROM, reserved
EEPROM and diagnostics and control spaces for future
standards definition, as well as Avago Technologies-specific functions.
Temperature is measured on the AFBR-720XPDZ using sensing circuitry mounted on the internal PCB. The measured temperature will generally be cooler
than laser junction and warmer than XFP case and can
be indirectly correlated to XFP case or laser junction
temperature using thermal resistance and capacitance
modeling. This measurement can be used to observe
drifts in thermal operating point or to detect extreme
temperature fluctuations such as a failure in the system
thermal control. For more information on correlating
internal temperature to case or laser junction contact Avago Technologies.
Predictive Failure Identification
The diagnostic information allows the host system to
identify potential link problems. Once identified, a “fail
over” technique can be used to isolate and replace suspect devices before system uptime is impacted.
Compliance Prediction
The real-time diagnostic parameters can be monitored
to alert the system when operating limits are exceeded
and compliance cannot be ensured. As an example, the
real time average receive optical power can be used to
assess the compliance of the cable plant and remote
transmitter.
Fault Isolation
The diagnostic information can allow the host to pinpoint the location of a link problem and accelerate system servicing and minimize downtime.
Component Monitoring
As part of host system qualification and verification,
real time transceiver diagnostic information can be
combined with system level monitoring to ensure performance and operating environment are meeting application requirements.
Transmitter Laser DC Bias Current
Laser bias current is measured using sensing circuitry
located on the transmitter laser driver IC. Normal variations in laser bias current are expected to accommodate
the impact of changing transceiver temperature and
supply voltage operating points. The AFBR-720XPDZ
uses a closed loop laser bias feedback circuit to maintain
constant optical power. This circuit compensates for normal laser parametric variations in quantum efficiency,
forward voltage and lasing threshold due to changing
transceiver operating points.
Transmitted Average Optical Output Power
Variations in average optical power are not expected
under normal operation because the AFBR-720XPDZ
uses a closed loop laser bias feedback circuit to maintain constant optical power. This circuit compensates
for normal laser parametric variations due to changing
transceiver operating points. Only under extreme laser
bias conditions will significant drifting in transmitted
average optical power be observable. Therefore it is recommended Tx average optical power be used for fault isolation, rather than predictive failure purposes.
Received Average Optical Input Power
Received average optical power measurements are a
valuable asset for installers to verify cable plant compliance. Drifts in average power can be observed from the
cable plant and remote transmitter for potential predictive failure use. Received average optical power can be
used for fault isolation.
Auxilliary Monitors
In addition to the parameters mentioned above, 3.3V
Supply Voltage (AUX1) is also reported as auxilliary parameter 1.
11
Mechanical Specifications
Package Dimensions
Figure 6a. Module Drawing
Figure 6b. Module Drawing
12
Figure 7. XFP host board mechanical layout
13
Application Support
Electrostatic Discharge (ESD)
An Evaluation Kit and Reference Designs are available
to assist in evaluation of the AFBR-720XPDZ. Please contact your local Field Sales representative for availability
and ordering details.
There are two conditions in which immunity to ESD
damage is important. Table 13 documents the ESD immunity to both of these conditions.
Regulatory Compliance
The transceiver Regulatory Compliance performance is
provided in Table 2 as a figure of merit to assist the designer. The overall equipment design will determine the
certification level.
The first condition is static discharge to the transceiver
during handling such as when the transceiver is inserted
into the transceiver port. To protect the transceiver, it is
important to use normal ESD handling precautions including the use of grounded wrist straps, work benches,
and floor mats in ESD controlled areas. The ESD sensitivity of the AFBR-720XPDZ is compatible with typical
industry production environments. The second condition is static discharge 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 AFBR-720XPDZ exceeds
typical industry standards. Regulatory Compliance
Feature
Test Method
Performance
Electrostatic Discharge (ESD)
to the electrical pins of the
XFP module
MIL-STD-883
Method 3015
500 Volts to the high speed pins, 2000 Volts to the low speed pins
Electrostatic Discharge (ESD)
to the Duplex LC Receptacle
Variation of IEC 61000-4-2
Typically, no damage occurs with 25 kV when the duplex LC connector
receptacle is contacted.
Electrostatic Discharge (ESD)
to the Optical Connector
GR1089
8 KV on the electrical faceplate with
device inserted into a panel.
Electrostatic Discharge (ESD)
to the Optical Connector
IEC6100-4-2
Air discharge of 15 kV(min) contact to connector w/o damage
Electromagnetic Interference
(EMI)
FCC Class B
CENELEC EN55022 Class B
(CISPR 22A)
VCCI Class 1
System margins are dependent on
customer board and chassis design.
Immunity
Variation of IEC 61000-4-3
No bit error at 10V/m, 10MHz to 1G w/o chassis enclosure
Laser Eye Safety and
Equipment Type Testing
US FDA CDRH AEL Class 1
US21 CFR, Subchapter J per Paragraphs 1002.10 and
1002.12.
CDRH certification # 9720151-072
TUV certification # R72071411
(IEC) EN60825-1: 1994 + A11+A2
(IEC) EN60825-2: 1994 + A1
(IEC) EN60950: 1992 + A1 + A2 + A3 + A4 + A11
Component Recognition
14
Underwriters Laboratories and Canadian Standards
Association Joint Component Recognition for Information Technology Equipment Including Electrical
Business Equipment
UL file # E173874
Immunity
Caution
The transceivers have a shielded design to provide excellent immunity to radio-frequency electromagnetic fields
which may be present in some operating environments. The AFBR-720XPDZ contains no user serviceable parts. Tampering with or modifying the performance of the
AFBR-720XPDZ will result in voided product warranty. It may also result in improper operation of the AFBR720XPDZ circuitry, and possible overstress of the laser
source. Device degradation or product failure may result.
Connection of the AFBR-720XPDZ to a non-approved optical source, operating above the recommended absolute
maximum conditions may be considered an act of modifying or manufacturing a laser product. The person(s)
performing such an act is required by law to recertify and
reidentify the laser product under the provisions of U.S.
21 CFR (Subchapter J) and the TUV.
Electromagnetic Interference (EMI)
Most equipment designs using the AFBR-720XPDZ are
subject to the requirements of the FCC in the United
States, CENELEC EN55022 (CISPR 22) in Europe and VCCI
in Japan. The metal housing and shielded design of the
AFBR-720XPDZ minimizes EMI and provides excellent EMI performance.
Eye Safety
The AFBR-720XPDZ transceivers provide Class 1 eye safety by design. Avago Technologies has tested the transceiver design for regulatory compliance, under normal
operating conditions and under single fault conditions. See Table 2.
Flammability
The AFBR-720XPDZ is compliant to UL 94V-0.
Ordering Information
Please contact your local field sales engineer or one of
Avago Technologies franchised distributors for ordering information. For technical information, please visit Avago Technologies’ WEB page at www.avagotech.com
or contact Avago Technologies Semiconductor Products
Customer Response Center at 1-800-235-0312. For information related to XFP MSA documentation visit www.
xfpmsa.org
For product information and a complete list of distributors, please go to our web site: www.avagotech.com
Avago, Avago Technologies, and the A logo are trademarks of Avago Technologies, Limited in the United States and other countries.
Data subject to change. Copyright © 2007 Avago Technologies Limited. All rights reserved.
AV02-0438EN - August 17, 2007