AGILENT HFBR

Agilent HFBR-5903/5903E/5903A
FDDI, Fast Ethernet Transceivers
in 2 x 5 Package Style
Data Sheet
Description
The HFBR-5900 family of transceivers from Agilent provide the
system designer with products
to implement a range of FDDI
and ATM (Asynchronous
Transfer Mode) designs at the
100 Mb/s125 MBd rate.
The transceivers are all supplied
in the new industry standard
2 x 5 DIP style with a MT-RJ
fiber connector interface.
FDDI PMD, ATM and Fast Ethernet
2 km Backbone Links
The HFBR-5903 is a 1300 nm
product with optical
performance compliant with the
FDDI PMD standard. The FDDI
PMD standard is ISO/IEC
9314-3: 1990 and ANSI X3.166 1990.
These transceivers for 2 km
multimode fiber backbones are
supplied in the small 2 x 5 MTRJ package style for those
designers who want to avoid the
larger MIC/R (Media Interface
Connector/Receptacle) defined
in the FDDI PMD standard.
Agilent also provides several
other FDDI products compliant
with the PMD and SM-PMD
standards. These products are
available with MIC/R, ST©, SC
and FC connector styles. They
are available in the 1 x 9, 1 x 13
and 2 x 11 transceiver and 16
pin transmitter/receiver package
styles for those designs that
require these alternate
configurations.
The HFBR-5903 is also useful for
both ATM 100 Mb/s interfaces
and Fast Ethernet 100 Base-FX
interfaces. The ATM Forum
User-Network Interface (UNI)
Standard, Version 3.0, defines
the Physical Layer for 100 Mb/s
Multimode Fiber Interface for
ATM in Section 2.3 to be the
FDDI PMD Standard. Likewise,
the Fast Ethernet Alliance
defines the Physical Layer for
100 Base-FX for Fast Ethernet to
be the FDDI PMD Standard.
ATM applications for physical
layers other than 100 Mb/s
Multimode Fiber Interface are
supported by Agilent. Products
are available for both the singlemode and the multimode fiber
SONET OC-3c (STS-3c), SDH
(STM-1) ATM interfaces and the
155 Mb/s-194 MBd multimode
fiber ATM interface as specified
in the ATM Forum UNI.
Contact your Agilent sales
representative for information
on these alternative FDDI and
ATM products.
Features
• Multisourced 2 x 5 package style
with MT-RJ receptacle
• Single +3.3 V power supply
• Wave solder and aqueous wash
process compatible
• Manufactured in an ISO 9002
certified facility
• Full compliance with the optical
performance requirements of the
FDDI PMD standard
• Full compliance with the FDDI
LCF-PMD standard
• Full compliance with the optical
performance requirements of the
ATM 100 Mb/s physical layer
• Full compliance with the optical
performance requirements of
100 Base-FX version of
IEEE 802.3u
Applications
• Multimode fiber backbone links
• Multimode fiber wiring closet to
desktop links
Ordering Information
The HFBR-5903 1300 nm
product is available for
production orders through the
Agilent Component Field Sales
Offices and Authorized
Distributors world wide.
HFBR-5903
=
HFBR-5903E =
Shield
HFBR-5903A =
0°C to +70°C
No Shield
0°C to +70°C
Extended
-40°C to +85°C
No Shield.
Transmitter Sections
The transmitter section of the
HFBR-5903 utilizes a 1300 nm
Surface Emitting InGaAsP LED.
This LED is packaged in the
optical subassembly portion of
the transmitter section. It is
driven by a custom silicon IC
which converts differential
PECL logic signals, ECL
referenced (shifted) to a +3.3 V
supply, into an analog LED drive
current.
Receiver Sections
The receiver section of the
HFBR-5903 utilizes an InGaAs
PIN photodiode coupled to a
custom silicon transimpedance
preamplifier IC. It is packaged
in the optical subassembly
portion of the receiver.
This PIN/preamplifier combination is coupled to a custom
quantizer IC which provides the
final pulse shaping for the logic
output and the Signal Detect
function. The Data output is differential. The Signal Detect
output is single-ended. Both Data
and Signal Detect outputs are
PECL compatible, ECL
referenced (shifted) to a +3.3 V
power supply. The receiver
outputs, Data Out and Data Out
Bar, are squelched at Signal
Detect Deassert. That is, when
the light input power decreases
to a typical -38 dBm or less, the
Signal Detect Deasserts, i.e. the
Signal Detect output goes to a
PECL low state. This forces the
receiver outputs, Data Out and
Data Out Bar to go to steady
PECL levels High and Low
respectively.
Package
The overall package concept for
the Agilent transceiver consists
of the following basic elements;
two optical subassemblies, an
electrical subassembly and the
housing as illustrated in
Figure 1.
The package outline drawing
and pin out are shown in
Figures 2 and 3. The details of
this package outline and pin out
are compliant with the multisource definition of the 2 x 5
DIP. The low profile of the
Agilent transceiver design
complies with the maximum
height allowed for the MT-RJ
connector over the entire length
of the package.
The optical subassemblies utilize
a high-volume assembly process
together with low-cost lens
elements which result in a costeffective building block.
The electrical subassembly consists of a high volume multilayer
printed circuit board on which
the IC and various surfacemounted passive circuit
elements are attached.
The receiver section includes an
internal shield for the electrical
and optical subassemblies to
ensure high immunity to
external EMI fields.
The outer housing is electrically
conductive. The MT-RJ port is
molded of filled nonconductive
plastic to provide mechanical
strength and electrical isolation.
The solder posts of the Agilent
design are isolated from the
internal circuit of the
transceiver.
The transceiver is attached to a
printed circuit board with the
ten signal pins and the two
solder posts which exit the
bottom of the housing. The two
solder posts provide the primary
mechanical strength to
withstand the loads imposed on
the transceiver by mating with
the MT-RJ connectored fiber
cables.
RX SUPPLY
DATA OUT
DATA OUT
QUANTIZER IC
SIGNAL
DETECT
PIN PHOTODIODE
PRE-AMPLIFIER
SUBASSEMBLY
R X GROUND
MT-RJ
RECEPTACLE
TX GROUND
DATA IN
DATA IN
LED DRIVER IC
TX SUPPLY
Figure 1. Block Diagram.
2
LED OPTICAL
SUBASSEMBLY
13.97
(0.55)
MIN.
4.5 ±0.2
(0.177 ±0.008)
(PCB to OPTICS
CENTER LINE)
5.15
(0.20)
(PCB to OVERALL
RECEPTACLE CENTER
LINE)
FRONT VIEW
Case Temperature
Measurement Point
9.6
13.59
(0.535) (0.378)
MAX. MAX.
TOP VIEW
10.16
(0.4)
Pin 1
7.59
(0.299)
8.6
(0.339)
12
(0.472)
1.778
(0.07)
+0
-0.2
(+000)
(0.024)
(-008)
Ø 0.61
Ø1.5
(0.059)
17.778
(0.7)
7.112
(0.28)
49.56 (1.951) REF.
37.56 (1.479) MAX.
9.3
9.8
(0.386) (0.366)
MAX. MAX.
SIDE VIEW
3.3
(0.13)
Ø 1.07
(0.042)
DIMENSIONS IN MILLIMETERS (INCHES)
NOTES:
1. THIS PAGE DESCRIBES THE MAXIMUM PACKAGE OUTLINE, MOUNTING STUDS, PINS AND THEIR RELATIONSHIPS TO EACH OTHER.
2. TOLERANCED TO ACCOMMODATE ROUND OR RECTANGULAR LEADS.
3. ALL 12 PINS AND POSTS ARE TO BE TREATED AS A SINGLE PATTERN.
4. THE MT-RJ HAS A 750 µm FIBER SPACING.
5. THE MT-RJ ALIGNMENT PINS ARE IN THE MODULE.
6. FOR SM MODULES, THE FERRULE WILL BE PC POLISHED (NOT ANGLED).
7. SEE MT-RJ TRANSCEIVER PIN OUT DIAGRAM FOR DETAILS.
Figure 2. Package Outline Drawing
3
RX
TX
Mounting
Studs/Solder
Posts
Top
View
RECEIVER SIGNAL GROUND
RECEIVER POWER SUPPLY
SIGNAL DETECT
RECEIVER DATA OUT BAR
RECEIVER DATA OUT
o
o
o
o
o
1
2
3
4
5
10 o
9o
8o
7o
6o
TRANSMITTER DATA IN BAR
TRANSMITTER DATA IN
TRANSMITTER DISABLE (LASER BASED PRODUCTS ONLY)
TRANSMITTER SIGNAL GROUND
TRANSMITTER POWER SUPPLY
Figure 3. Pin Out Diagram.
Pin Descriptions:
Pin 1 Receiver Signal Ground VEE RX:
Directly connect this pin to the
receiver ground plane.
Pin 2 Receiver Power Supply VCC
RX:
Provide +3.3 V dc via the
recommended receiver power
supply filter circuit. Locate the
power supply filter circuit as
close as possible to the VCC RX
pin.
Pin 3 Signal Detect SD:
Normal optical input levels to
the receiver result in a logic “1”
output.
Low optical input levels to the
receiver result in a fault
condition indicated by a logic
“0” output.
This Signal Detect output can be
used to drive a PECL input on
an upstream circuit, such as
Signal Detect input or Loss of
Signal-bar.
Pin 4 Receiver Data Out Bar RD-:
No internal terminations are
provided. See recommended
circuit schematic.
4
Pin 5 Receiver Data Out RD+:
No internal terminations are
provided. See recommended
circuit schematic.
Pin 9 Transmitter Data In TD+:
No internal terminations are
provided. See recommended
circuit schematic.
Pin 6 Transmitter Power Supply
VCC TX:
Provide +3.3 V dc via the
recommended transmitter
power supply filter circuit.
Locate the power supply filter
circuit as close as possible to the
VCC TX pin.
Pin 10 Transmitter Data In Bar TD-:
No internal terminations are
provided. See recommended
circuit schematic.
Pin 7 Transmitter Signal Ground
VEE TX:
Directly connect this pin to the
transmitter ground plane.
Pin 8 Transmitter Disable TDIS:
No internal connection. Optional
feature for laser based products
only. For laser based products
connect this pin to +3.3 V TTL
logic high “1” to disable module.
To enable module connect to
TTL logic low “0”.
Mounting Studs/Solder Posts
The mounting studs are
provided for transceiver
mechanical attachment to the
circuit board. It is
recommended that the holes in
the circuit board be connected to
chassis ground.
The area under the curves
represents the remaining OPB at
any link length, which is
available for overcoming nonfiber cable related losses.
The following information is
provided to answer some of the
most common questions about
the use of these parts.
Transceiver Optical Power Budget
versus Link Length
Optical Power Budget (OPB) is
the available optical power for a
fiber optic link to accommodate
fiber cable losses plus losses due
to in-line connectors, splices,
optical switches, and to provide
margin for link aging and
unplanned losses due to cable
plant reconfiguration or repair.
Figure 4 illustrates the predicted
OPB associated with the
transceiver specified in this data
sheet at the Beginning of Life
(BOL). These curves represent
the attenuation and chromatic
plus modal dispersion losses
associated with the 62.5/125 µm
and 50/125 µm fiber cables only.
12
HFBR-5903, 62.5/125 µm
OPTICAL POWER BUDGET (dB)
10
8
6
HFBR-5903
50/125 µm
4
2
0
1.0
1.5
2.0
0.3 0.5
FIBER OPTIC CABLE LENGTH (km)
2.5
Figure 4. Typical Optical Power Budget at BOL
versus Fiber Optic Cable Length.
5
Agilent LED technology has
produced 1300 nm LED devices
with lower aging characteristics
than normally associated with
these technologies in the
industry. The industry convention is 1.5 dB aging for 1300 nm
LEDs. The Agilent 1300 nm
LEDs will experience less than
1 dB of aging over normal commercial equipment mission life
periods. Contact your Agilent
sales representative for
additional details.
Figure 4 was generated with a
Agilent fiber optic link model
containing the current industry
conventions for fiber cable
specifications and the FDDI
PMD and LCF-PMD optical
parameters. These parameters
are reflected in the guaranteed
performance of the transceiver
specifications in this data sheet.
This same model has been used
extensively in the ANSI and
IEEE committees, including the
ANSI X3T9.5 committee, to
establish the optical
performance requirements for
various fiber optic interface
standards. The cable parameters
used come from the ISO/IEC
JTC1/SC 25/WG3 Generic
Cabling for Customer Premises
per DIS 11801 document and the
EIA/TIA-568-A Commercial
Building Telecommunications
Cabling Standard per SP-2840.
Transceiver Signaling Operating
Rate Range and BER Performance
For purposes of definition, the
symbol (Baud) rate, also called
signaling rate, is the reciprocal
of the shortest symbol time. Data
rate (bits/sec) is the symbol rate
divided by the encoding factor
used to encode the data
(symbols/bit).
When used in FDDI and ATM
100 Mb/s applications the
performance of the 1300 nm
transceivers is guaranteed over
the signaling rate of 10 MBd to
125 MBd to the full conditions
listed in individual product
specification tables.
The transceivers may be used
for other applications at signaling rates outside of the 10 MBd
to 125 MBd range with some
penalty in the link optical power
budget primarily caused by a
reduction of receiver sensitivity.
Figure 5 gives an indication of
the typical performance of these
1300 nm products at different
rates.
2.5
TRANSCEIVER RELATIVE POWER BUDGET
AT CONSTANT BER (dB)
Application Information
The Applications Engineering
group is available to assist you
with the technical understanding and design trade-offs
associated with these transceivers. You can contact them
through your Agilent sales
representative.
2
1.5
1
0.5
0
-0.5
-1
0
25
50
75
100
125
150
175
200
SIGNAL RATE (MBd)
CONDITIONS:
1. PRBS 2 7-1
2. DATA SAMPLED AT CENTER OF DATA SYMBOL.
3. BER = 10 -6
4. TA= +25 ˚C
5. VCC = 3.3 V dc
6. INPUT OPTICAL RISE/FALL TIMES = 1.0/ 2.1 ns.
Figure 5. Transceiver Relative Optical Power
Budget at Constant BER vs. Signaling Rate.
These transceivers can also be
used for applications which
require different Bit Error Rate
(BER) performance. Figure 6
illustrates the typical trade-off
between link BER and the
receivers input optical power
level.
The Agilent 1300 nm
transmitters will tolerate the
worst case input electrical jitter
allowed in these tables without
violating the worst case output
jitter requirements of Sections
8.1 Active Output Interface of
the FDDI PMD and LCF-PMD
standards.
The Agilent 1300 nm receivers
will tolerate the worst case input
optical jitter allowed in Sections
8.2 Active Input Interface of the
FDDI PMD and LCF-PMD
standards without violating the
worst case output electrical
jitter allowed in Table E1 of
Annex E.
The jitter specifications stated in
the following 1300 nm
transceiver specification tables
are derived from the values in
Table E1 of Annex E. They
represent the worst case jitter
contribution that the transceivers are allowed to make to
the overall system jitter without
violating the Annex E allocation
example. In practice the typical
contribution of the Agilent transceivers is well below these
maximum allowed amounts.
Recommended Handling Precautions
Agilent recommends that normal
static precautions be taken in
the handling and assembly of
these transceivers to prevent
damage which may be induced
by electrostatic discharge (ESD).
The HFBR-5900 series of
transceivers meet MIL-STD-883C
Method 3015.4 Class 2 products.
Figure 7. Recommended Decoupling and Termination Circuits
6
1 x 10 -2
1 x 10 -3
BIT ERROR RATE
Transceiver Jitter Performance
The Agilent 1300 nm
transceivers are designed to
operate per the system jitter
allocations stated in Table E1 of
Annex E of the FDDI PMD and
LCF-PMD standards.
1 x 10 -4
HFBR-5903 SERIES
1 x 10 -5
1 x 10 -6
CENTER OF SYMBOL
1 x 10 -7
1 x 10 -8
1 x 10 -9
1 x 10 -10
1 x 10 -11
1 x 10 -12
-6
-4
-2
2
0
RELATIVE INPUT OPTICAL POWER - dB
4
CONDITIONS:
1. 125 MBd
2. PRBS 2 7 -1
3. CENTER OF SYMBOL SAMPLING
4. TA = +25 ˚C
5. VCC = 3.3 V dc
6. INPUT OPTICAL RISE/FALL TIMES = 1.0/ 2.1 ns.
Figure 6. Bit Error Rate vs. Relative Receiver
Input Optical Power.
Care should be used to avoid
shorting the receiver data or
signal detect outputs directly to
ground without proper current
limiting impedance.
Solder and Wash Process
Compatibility
The transceivers are delivered
with protective process plugs
inserted into the MT-RJ
connector receptacle. This
process plug protects the optical
subassemblies during wave
solder and aqueous wash
processing and acts as a dust
cover during shipping.
These transceivers are compatible with either industry
standard wave or hand solder
processes.
Figure 8. Alternative Termination Circuits
7
Shipping Container
The transceiver is packaged in a
shipping container designed to
protect it from mechanical and
ESD damage during shipment or
storage.
Board Layout - Decoupling Circuit,
Ground Planes and Termination
Circuits
It is important to take care in
the layout of your circuit board
to achieve optimum performance from these transceivers.
Figure 7 provides a good
example of a schematic for a
power supply decoupling circuit
that works well with these parts.
It is further recommended that a
continuous ground plane be
provided in the circuit board
directly under the transceiver to
provide a low inductance
ground for signal return current.
This recommendation is in
keeping with good high
frequency board layout
practices. Figures 7 and 8 show
two recommended termination
schemes.
Board Layout - Hole Pattern
The Agilent transceiver complies
with the circuit board “Common
Transceiver Footprint” hole
pattern defined in the original
multisource announcement
which defined the 2 x 5 package
style. This drawing is reproduced in Figure 9 with the
addition of ANSI Y14.5M
compliant dimensioning to be
used as a guide in the mechanical layout of your circuit board.
Board Layout - Art Work
The Applications Engineering
group has developed Gerber file
artwork for a multilayer printed
circuit board layout incorporating the recommendations above.
Contact your local Agilent sales
representative for details.
Regulatory Compliance
These transceiver products are
intended to enable commercial
system designers to develop
equipment that complies with
the various international
regulations governing certification of Information Technology
Equipment. See the Regulatory
Compliance Table for details.
Additional information is
available from your Agilent sales
representative.
Electrostatic Discharge (ESD)
There are two design cases in
which immunity to ESD damage
is important.
The first case is during handling
of the transceiver prior to
mounting it on the circuit board.
It is important to use normal
ESD handling precautions for
ESD sensitive devices. These
precautions include using
grounded wrist straps, work
benches, and floor mats in ESD
controlled areas.
Ø 1.4 ±0.1
(0.055±0.004)
Spacing Of Front
Housing Leads Holes
7.11
Ø 1.4 ±0.1
KEEP OUT AREA (0.055±0.004)
(0.28)
FOR PORT PLUG
7
(0.276)
3.56
(0.14)
The second case to consider is
static discharges to the exterior
of the equipment chassis containing the transceiver parts. To
the extent that the MT-RJ
connector is exposed to the
outside of the equipment chassis
it may be subject to whatever
ESD system level test criteria
that the equipment is intended
to meet.
Holes For
Housing
Leads
Ø 1.4 ±0.1
(0.055±0.004)
10.16
(0.4) 13.97
(0.55)
MIN.
10.8
(0.425)
3.08
(0.121)
13.34 7.59
(0.525)(0.299)
3
(0.118)
27
(1.063)
3
(0.118)
6
(0.236)
1.778
4.57(0.07)
(0.18)
17.78
(0.7)
9.59
(0.378 )
2
(0.079)
Ø 2.29
(0.09)
Ø 0.81 ±0.1
(0.032±0.004)
7.112
(0.28)
3.08
(0.121)
DIMENSIONS IN MILLIMETERS (INCHES)
NOTES:
1. THIS FIGURE DESCRIBES THE RECOMMENDED CIRCUIT BOARD LAYOUT FOR THE MT-RJ
TRANSCEIVER PLACED AT .550 SPACING.
2. THE HATCHED AREAS ARE KEEP-OUT AREAS RESERVED FOR HOUSING STANDOFFS. NO
METAL TRACES OR GROUND CONNECTION IN KEEP-OUT AREAS.
3. 10 PIN MODULE REQUIRES ONLY 16 PCB HOLES, INCLUDING 4 PACKAGE GROUNDING TAB
HOLES CONNECTED TO SIGNAL GROUND.
4. THE SOLDER POSTS SHOULD BE SOLDERED TO CHASSIS GROUND FOR MECHANICAL
INTEGRITY AND TO ENSURE FOOTPRINT COMPATIBILITY WITH OTHER SFF TRANSCEIVERS.
Figure 9. Recommended Board Layout Hole Pattern
8
Regulatory Compliance Table
Feature
Test Method
Performance
Electrostatic Discharge
(ESD) to the Electrical Pins
Electrostatic Discharge
ESD) to the MT-RJ Receptacle
Electromagnetic
Interference (EMI)
MIL-STD-883C
Method 3015.4
Variation of
IEC 801-2
FCC Class B
CENELEC CEN55022
VCCI Class 2
Variation of IEC 801-3
Meets Class 2 (2000 to 3999 Volts).
Withstand up to 2200 V applied between electrical pins.
Typically withstand at least 25 kV without damage when the MT-RJ
Connector Receptacle is contacted by a Human Body Model probe.
Transceivers typically provide a 10 dB margin to the noted standard limits
when tested at a certified test range with the transceiver mounted to a
circuit card without a chassis enclosure.
Typically show no measurable effect from a 10 V/m field swept from 10 to
450 MHz applied to the transceiver when mounted to a circuit card without a
chassis enclosure.
Compliant per Agilent testing under single fault conditions.
TUV Certification: LED Class 1
Immunity
Eye Safety
IEC 825 Issue 1 1993:11
Class 1
CENELEC EN60825 Class 1
Electromagnetic Interference (EMI)
Most equipment designs utilizing
this high speed transceiver from
Agilent will be required to meet
the requirements of FCC in the
United States, CENELEC
EN55022 (CISPR 22) in Europe
and VCCI in Japan.
Immunity
Equipment utilizing these
transceivers will be subject to
radio-frequency electromagnetic
fields in some environments.
These transceivers have a high
immunity to such fields.
3.8
(0.15 )
10.8 ±0.1
(0.425±0.004)
1
(0.039)
9.8 ±0.1
(0.386±0.004)
For additional information
regarding EMI, susceptibility,
ESD and conducted noise testing
procedures and results on the 1 x
9 Transceiver family, please
refer to Applications Note 1075,
Testing and Measuring Electromagnetic Compatibility
Performance of the HFBR-510X/
-520X Fiber Optic Transceivers.
Transceiver Reliability and
Performance Qualification Data
The 2 x 5 transceivers have
passed Agilent reliability and
performance qualification
testing and are undergoing
ongoing quality and reliability
monitoring. Details are available
from your Agilent sales
representative.
These transceivers are
manufactured at the Agilent
Singapore location which is an
ISO 9002 certified facility.
13.97
(0.55)
MIN.
0.25 ±0.1
(0.01 ±0.004)
(TOP OF PCB TO
BOTTOM OF
OPENING)
DIMENSIONS IN MILLIMETERS (INCHES)
Figure 10. Recommended Panel Mounting
9
14.79
(0.589)
Applications Support Materials
Contact your local Agilent
Component Field Sales Office for
information on how to obtain
PCB layouts and evaluation
boards for the 2 x 5 transceivers.
200
4.40
1.975
1.25
3.0
180
4.850
1.525
0.525
10.0
SPECTRAL WIDTH (FWHM) - nm
160
5.6
3.5
2.0
0.075
1.025
1.00
0.975
140
2.5
0.90
3.0
100% TIME
INTERVAL
t r/f - TRANSMITTER
120
OUTPUT OPTICAL
3.5
RISE/FALL TIMES - ns
100
1200
1300
1320
1340
1360
1380
λ C - TRANSMITTER OUTPUT OPTICAL
CENTER WAVELENGTH - nm
HFBR-5903 FDDI TRANSMITTER TEST RESULTS
OF λC, ∆λ AND tr/f ARE CORRELATED AND
COMPLY WITH THE ALLOWED SPECTRAL WIDTH
AS A FUNCTION OF CENTER WAVELENGTH FOR
VARIOUS RISE AND FALL TIMES.
RELATIVE AMPLITUDE
∆λ - TRANSMITTER OUTPUT OPTICAL
1.5
40 ± 0.7
± 0.725
0.50
± 0.725
0% TIME
INTERVAL
Figure 11. Transmitter Output Optical Spectral
Width (FWHM) vs. Transmitter Output Optical
Center Wavelength and Rise/Fall Times.
0.10
0.025
0.0
0.025
0.05
0.075
1.525
5.6
0.525
RELATIVE INPUT OPTICAL POWER (dB)
10.0
6
4.850
80 ± 500 ppm
5
TIME - ns
THE HFBR-5903 OUTPUT OPTICAL PULSE SHAPE SHALL FIT WITHIN THE BOUNDARIES OF THE
PULSE ENVELOPE FOR RISE AND FALL TIME MEASUREMENTS.
4
2.5 x 10
-10
1.975
4.40
BER
3
Figure 12. Output Optical Pulse Envelope.
2
1.0 x 10-12 BER
1
-31.0 dBm
0
-4
-3
-2
-1
0
1
2
3
4
P A (P O + 1.5 dB < P A < -31.0 dBm)
EYE SAMPLING TIME POSITION (ns)
Figure 13. Relative Input Optical Power vs.
Eye Sampling Time Position.
PO = MAX (PS OR -45.0 dBm)
(PS = INPUT POWER FOR BER < 10 2 )
OPTICAL POWER
1.TA = +25 ˚C
2. VCC = 3.3 V dc
3. INPUT OPTICAL RISE/FALL TIMES = 1.0/2.1 ns.
4. INPUT OPTICAL POWER IS NORMALIZED TO
CENTER OF DATA SYMBOL.
5. NOTE 19 AND 20 APPLY.
INPUT OPTICAL POWER
( > 1.5 dB STEP INCREASE)
INPUT OPTICAL POWER
( > 4.0 dB STEP DECREASE)
-45.0 dBm
SIGNAL _ DETECT(ON)
SIGNAL
DETECT
OUTPUT
CONDITIONS:
MIN (P O + 4.0 dB OR -31.0 dBm)
ANS _ MAX
AS _ MAX
SIGNAL _DETECT (OFF)
TIME
AS _ MAX - MAXIMUM ACQUISITION TIME (SIGNAL).
AS _ MAX IS THE MAXIMUM SIGNAL _ DETECT ASSERTION TIME FOR THE STATION.
AS _ MAX SHALL NOT EXCEED 100.0 µs. THE DEFAULT VALUE OF AS _ MAX IS 100.0 µs.
ANS _ MAX - MAXIMUM ACQUISITION TIME (NO SIGNAL).
ANS _ MAX IS THE MAXIMUM SIGNAL _ DETECT DEASSERTION TIME FOR THE STATION.
ANS _ MAX SHALL NOT EXCEED 350 µs. THE DEFAULT VALUE OF AS _ MAX IS 350 µs.
Figure 14. Signal Detect Thresholds and Timing.
10
Absolute Maximum Ratings
Stresses in excess of the absolute maximum ratings can cause catastrophic damage to the device. Limits apply to each parameter in
isolation, all other parameters having values within the recommended operating conditions. It should not be assumed that limiting values
of more than one parameter can be applied to the product at the same time. Exposure to the absolute maximum ratings for extended
periods can adversely affect device reliability.
Parameter
Symbol
Minimum Typical
Maximum Unit
Storage Temperature
TS
-40
+100
Reference
°C
Lead Soldering Temperature
TSOLD
+260
°C
Lead Soldering Time
tSOLD
10
sec.
Supply Voltage
VCC
-0.5
3.6
V
Data Input Voltage
VI
-0.5
VCC
V
Differential Input Voltage (p-p)
VD
2.0
V
Output Current
IO
50
mA
Note 1
Recommended Operating Conditions
Parameter
Symbol
Minimum Typical
Maximum Unit
Reference
HFBR-5903/5903E
TA
0
+70
°C
Note A
HFBR-5903A
Supply Voltage
TA
VCC
-40
3.135
+85
3.465
°C
V
Note B
Data Input Voltage - Low
VIL - VCC
-1.810
-1.475
V
Data Input Voltage - High
VIH - VCC
-1.165
Data and Signal Detect Output Load
RL
50
W
Differential Input Voltage (p-p)
VD
0.800
V
Ambient Operating Temperature
-0.880
V
Note 2
Notes:
A. Ambient Operating Temperature corresponds to transceiver case temperature of 0°C mininum to +85 °C maximum with necessary airflow applied.
Recommended case temperature measurement point can be found in Figure 2.
B. Ambient Operating Temperature corresponds to transceiver case temperature of -40 °C mininum to +100 °C maximum with necessary airflow
applied. Recommended case temperature measurement point can be found in Figure 2.
Transmitter Electrical Characteristics
HFBR-5903/5903E (TA = 0°C to +70°C, VCC = 3.135 V to 3.465 V)
HFBR-5903A (TA = -40°C to +85°C, VCC = 3.135 V to 3.465 V)
Parameter
Symbol
Minimum Typical
Maximum Unit
Reference
Supply Current
ICC
133
175
mA
Note 3
Power Dissipation
PDISS
0.45
0.60
W
Note 5a
350
µA
Data Input Current - Low
IIL
Data Input Current - High
IIH
-350
-2
18
µA
Receiver Electrical Characteristics
HFBR-5903/5903E (TA = 0°C to +70°C, VCC = 3.135 V to 3.465 V)
HFBR-5903A (TA = -40°C to +85°C, VCC = 3.135 V to 3.465 V)
Parameter
Symbol
Minimum Typical
Maximum Unit
Reference
Supply Current
ICC
65
120
mA
Note 4
Power Dissipation
PDISS
0.225
0.415
W
Note 5b
Data Output Voltage - Low
VOL - VCC
-1.840
-1.620
V
Note 6
Data Output Voltage - High
VOH - VCC
-1.045
-0.880
V
Note 6
Data Output Rise Time
tr
0.35
2.2
ns
Note 7
Data Output Fall Time
tf
0.35
2.2
ns
Note 7
Signal Detect Output Voltage - Low
VOL - VCC
-1.840
-1.620
V
Note 6
Signal Detect Output Voltage - High
VOH - VCC
-1.045
-0.880
V
Note 6
Signal Detect Output Rise Time
tr
0.35
2.2
ns
Note 7
Signal Detect Output Fall Time
tf
0.35
2.2
ns
Note 7
Power Supply Noise Rejection
PSNR
11
50
mV
Transmitter Optical Characteristics
HFBR-5903/5903E (TA = 0°C to +70°C, VCC = 3.135 V to 3.465 V)
HFBR-5903A (TA = -40°C to +85°C, VCC = 3.135 V to 3.465 V)
Parameter
Output Optical Power
62.5/125 µm, NA = 0.275 Fiber
Output Optical Power
50/125 µm, NA = 0.20 Fiber
Optical Extinction Ratio
BOL
EOL
BOL
EOL
Symbol
Minimum Typical
Maximum Unit
Reference
PO
-19
-20
-22.5
-23.5
-15.7
-14
dBm avg
Note 11
-20.3
-14
dBm avg
Note 11
0.05
-33
0.2
-27
-45
%
dB
dBm avg
Note 12
1380
nm
PO
Output Optical Power at
Logic Low "0" State
Center Wavelength
PO ("0")
Spectral Width - FWHM
- RMS
Optical Rise Time
Dl
lC
Note 13
1270
1308
tr
0.6
147
63
1.9
3.0
ns
Optical Fall Time
tf
0.6
1.6
3.0
ns
Duty Cycle Distortion Contributed
by the Transmitter
Data Dependent Jitter Contributed
by the Transmitter
Random Jitter Contributed
by the Transmitter
DCD
0.02
0.6
ns p-p
Note 14
Figure 11
Note 14
Figure 11
Note 14/15
Figure 11,12
Note 14/15
Figure 11,12
Note 16
DDJ
0.02
0.6
ns p-p
Note 17
RJ
0
0.69
ns p-p
Note 18
12
nm
Receiver Optical and Electrical Characteristics
HFBR-5903/5903E (TA = 0°C to +70°C, VCC = 3.135 V to 3.465 V)
HFBR-5903A (TA = -40°C to +85°C, VCC = 3.135 V to 3.465 V)
Parameter
Symbol
Maximum Unit
Reference
Input Optical Power
PIN Min (W)
Minimum Typical
-33.5
-31
dBm avg
Note 19
Minimum at Window Edge
Input Optical Power
PIN Min (C)
-34.5
-31.8
dBm avg
Figure 13
Note 20
Minimum at Eye Center
Input Optical Power Maximum
PIN Max
-14
dBm avg
Figure 13
Note 19
1270
-11.8
Operating Wavelength
l
1380
nm
Duty Cycle Distortion Contributed
DCD
0.02
0.4
ns p-p
Note 8
by the Receiver
Data Dependent Jitter Contributed
DDJ
0.35
1.0
ns p-p
Note 9
2.14
ns p-p
Note 10
-33
dBm avg
Note 21, 22
dBm avg
Figure 14
Note 23, 24
dB
Figure 14
Figure 14
by the Receiver
Random Jitter Contributed by the Receiver
RJ
Signal Detect - Asserted
PA
1.0
PD + 1.5 dB
Signal Detect - Deasserted
PD
-45
Signal Detect - Hysteresis
PA - PD
1.5
2.4
Signal Detect Assert Time
AS_Max
0
2
100
µs
Note 21, 22
(off to on)
Signal Detect Deassert Time
ANS_Max
0
5
350
µs
Figure 14
Note 23, 24
(on to off)
13
Figure 14
Notes:
1. This is the maximum voltage that can be
applied across the Differential Transmitter
Data Inputs to prevent damage to the input
ESD protection circuit.
2. The outputs are terminated with 50 Ω
connected to VCC -2 V.
3. The power supply current needed to
operate the transmitter is provided to
differential ECL circuitry. This circuitry
maintains a nearly constant current flow
from the power supply. Constant current
operation helps to prevent unwanted
electrical noise from being generated and
conducted or emitted to neighboring
circuitry.
4. This value is measured with the outputs
terminated into 50 Ω connected to
VCC - 2 V and an Input Optical Power level
of -14 dBm average.
5a. The power dissipation of the transmitter is
calculated as the sum of the products of
supply voltage and current.
5b. The power dissipation of the receiver is
calculated as the sum of the products of
supply voltage and currents, minus the sum
of the products of the output voltages and
currents.
6. This value is measured with respect to VCC
with the output terminated into
50 Ω connected to VCC - 2 V.
7. The output rise and fall times are measured
between 20% and 80% levels with the
output connected to VCC -2 V through 50
Ω.
8. Duty Cycle Distortion contributed by the
receiver is measured at the 50% threshold
using an IDLE Line State,
125 MBd (62.5 MHz square-wave), input
signal. The input optical power level is
-20 dBm average. See Application
Information - Transceiver Jitter Section for
further information.
9. Data Dependent Jitter contributed by
the receiver is specified with the FDDI DDJ
test pattern described in the FDDI PMD
Annex A.5. The input optical power level is
-20 dBm average. See Application Information - Transceiver Jitter Section for further
information.
10. Random Jitter contributed by the receiver
is specified with an IDLE Line State, 125
MBd (62.5 MHz square-wave), input signal.
The input optical power level is at maximum “PIN Min. (W)”. See Application
Information - Transceiver Jitter Section for
further information.
11. These optical power values are measured
with the following conditions:
• The Beginning of Life (BOL) to the End
of Life (EOL) optical power degradation
is typically 1.5 dB per the industry
convention for long wavelength LEDs.
The actual degradation observed in
Agilent’s
1300 nm LED products is < 1 dB, as
specified in this data sheet.
14
12.
13.
14.
15.
16.
17.
18.
• Over the specified operating voltage and
temperature ranges.
• With HALT Line State, (12.5 MHz
square-wave), input signal.
• At the end of one meter of noted optical
fiber with cladding modes removed.
The average power value can be converted
to a peak power value by adding 3 dB.
Higher output optical power transmitters
are available on special request. Please
consult with your local Agilent sales
representative for further details.
The Extinction Ratio is a measure of the
modulation depth of the optical signal. The
data “0” output optical power is compared
to the data “1” peak output optical power
and expressed as a percentage. With the
transmitter driven by a HALT Line State
(12.5 MHz square-wave) signal, the
average optical power is measured. The
data “1” peak power is then calculated by
adding 3 dB to the measured average
optical power. The data “0” output optical
power is found by measuring the optical
power when the transmitter is driven by a
logic “0” input. The extinction ratio is the
ratio of the optical power at the “0” level
compared to the optical power at the “1”
level expressed as a percentage or in
decibels.
The transmitter provides compliance with
the need for Transmit_Disable commands
from the FDDI SMT layer by providing an
Output Optical Power level of < -45 dBm
average in response to a logic “0” input.
This specification applies to either 62.5/
125 µm or 50/125 µm fiber cables.
This parameter complies with the FDDI
PMD requirements for the trade-offs
between center wavelength, spectral
width, and rise/fall times shown in
Figure 11.
This parameter complies with the optical
pulse envelope from the FDDI PMD shown
in Figure 12. The optical rise and fall times
are measured from 10% to 90% when the
transmitter is driven by the FDDI HALT Line
State (12.5 MHz square-wave) input signal.
Duty Cycle Distortion contributed by the
transmitter is measured at a 50% threshold
using an IDLE Line State,
125 MBd (62.5 MHz square-wave), input
signal. See Application Information Transceiver Jitter Performance Section of
this data sheet for further details.
Data Dependent Jitter contributed by the
transmitter is specified with the FDDI test
pattern described in FDDI PMD Annex A.5.
See Application Information - Transceiver
Jitter Performance Section of this data
sheet for further details.
Random Jitter contributed by the
transmitter is specified with an IDLE Line
State, 125 MBd (62.5 MHz square-wave),
input signal. See Application Information Transceiver Jitter Performance Section of
this data sheet for further details.
19. This specification is intended to indicate
the performance of the receiver section of
the transceiver when Input Optical Power
signal characteristics are present per the
following definitions. The Input Optical
Power dynamic range from the minimum
level (with a window time-width) to the
maximum level is the range over which the
receiver is guaranteed to provide output
data with a Bit Error Rate (BER) better than
or equal to 2.5 x 10-10.
• At the Beginning of Life (BOL)
• Over the specified operating temperature
and voltage ranges
• Input symbol pattern is the FDDI test
pattern defined in FDDI PMD Annex A.5
with 4B/5B NRZI encoded data that
contains a duty cycle base-line wander
effect of 50 kHz. This sequence causes a
near worst case condition for intersymbol interference.
• Receiver data window time-width is 2.13
ns or greater and centered at midsymbol. This worst case window timewidth is the minimum allowed
eye-opening presented to the FDDI PHY
PM_Data indication input (PHY input)
per the example in FDDI PMD Annex E.
This minimum window time-width of
2.13 ns is based upon the worst case
FDDI PMD Active Input Interface optical
conditions for peak-to-peak DCD (1.0
ns), DDJ (1.2 ns) and RJ (0.76 ns)
presented to the receiver.
To test a receiver with the worst case FDDI
PMD Active Input jitter condition requires
exacting control over DCD, DDJ and RJ
jitter components that is difficult to
implement with production test equipment.
The receiver can be equivalently tested to
the worst case FDDI PMD input jitter
conditions and meet the minimum output
data window time-width of 2.13 ns. This is
accomplished by using a nearly ideal input
optical signal (no DCD, insignificant DDJ
and RJ) and measuring for a wider window
time-width of 4.6 ns. This is possible due to
the cumulative effect of jitter components
through their superposition (DCD and DDJ
are directly additive and RJ components
are rms additive). Specifically, when a
nearly ideal input optical test signal is used
and the maximum receiver peak-to-peak
jitter contributions of DCD (0.4 ns), DDJ (1.0
ns), and RJ (2.14 ns) exist, the minimum
window time-width becomes 8.0 ns -0.4 ns 1.0 ns - 2.14 ns = 4.46 ns, or conservatively
4.6 ns. This wider window time-width of 4.6
ns guarantees the FDDI PMD Annex E
minimum window time-width of 2.13 ns
under worst case input jitter conditions to
the Agilent receiver.
• Transmitter operating with an IDLE Line
State pattern, 125 MBd (62.5 MHz
square-wave), input signal to simulate
any cross-talk present between the
transmitter and receiver sections of the
transceiver.
20. All conditions of Note 19 apply except that
the measurement is made at the center of
the symbol with no window time-width.
21. This value is measured during the transition
from low to high levels of input optical
power. At Signal Detect Deassert, the
receiver outputs Data Out and Data Out Bar
go to steady PECL levels High and Low
respectively.
22. The Signal Detect output shall be asserted
within 100 µs after a step increase of the
Input Optical Power. The step will be from
a low Input Optical Power, -45 dBm, into
the range between greater than PA, and -14
dBm. The BER of the receiver output will
be 10-2 or better during the time, LS_Max
(15 µs) after Signal Detect has been
asserted. See
Figure 14 for more information.
23. This value is measured during the transition
from high to low levels of input optical
power. The maximum value will occur
when the input optical power is either -45
dBm average or when the input optical
power yields a BER of 10-2 or larger,
whichever power is higher.
24. Signal detect output shall be de-asserted
within 350 µs after a step decrease in the
Input Optical Power from a level which is
the lower of; -31 dBm or PD + 4 dB (PD is
the power level at which signal detect was
deasserted), to a power level of
-45 dBm or less. This step decrease will
have occurred in less than 8 ns. The
receiver output will have a BER of 10-2 or
better for a period of 12 µs or until signal
detect is deasserted. The input data stream
is the Quiet Line State. Also, signal detect
will be deasserted within a maximum of 350
µs after the BER of the receiver output
degrades above 10-2 for an input optical
data stream that decays with a negative
ramp function instead of a step function.
See Figure 14 for more information. At
Signal Detect Deassert, the receiver
outputs Data Out and Data Out Bar go to
steady PECL levels High and Low
respectively.
15
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Data subject to change.
Copyright © 2002 Agilent Technologies, Inc.
Obsoletes: 5988-4673EN
October 31, 2002
5988-8033EN
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