ETC HFBR-1414

Low Cost, Miniature Fiber
Optic Components with ST ®,
SMA, SC and FC Ports
Technical Data
HFBR-0400 Series
HFBR-14xx Transmitters
HFBR-24xx Receivers
Features
Applications
• Meets IEEE 802.3 Ethernet
and 802.5 Token Ring
Standards
• Low Cost Transmitters and
Receivers
• Choice of ST ®, SMA, SC or
FC Ports
• 820 nm Wavelength
Technology
• Signal Rates up to 160
Megabaud
• Link Distances up to 2.7 km
• Specified with 50/125 µm,
62.5/125 µm, 100/140 µm,
and 200 µm HCS® Fiber
• Repeatable ST Connections
within 0.2 dB Typical
• Unique Optical Port Design
for Efficient Coupling
• Auto-Insertable and Wave
Solderable
• No Board Mounting Hardware Required
• Wide Operating
Temperature Range
-40°C to 85°C
• AlGaAs Emitters 100%
Burn-In Ensures High
Reliability
• Conductive Port Option
• Local Area Networks
• Computer to Peripheral
Links
• Computer Monitor Links
• Digital Cross Connect Links
• Central Office Switch/PBX
Links
• Video Links
• Modems and Multiplexers
• Suitable for Tempest
Systems
• Industrial Control Links
Description
The HFBR-0400 Series of components is designed to provide cost
effective, high performance fiber
optic communication links for
information systems and
industrial applications with link
distances of up to 2.7 kilometers.
With the HFBR-24X6, the 125
MHz analog receiver, data rates
of up to 160 megabaud are
attainable.
ST® is a registered trademark of AT&T.
HCS® is a registered trademark of the SpecTran Corporation.
Transmitters and receivers are
directly compatible with popular
“industry-standard” connectors:
ST, SMA, SC and FC. They are
completely specified with
multiple fiber sizes; including
50/125 µm, 62.5/125 µm, 100/
140 µm, and 200 µm.
Complete evaluation kits are
available for ST product
offerings; including transmitter,
receiver, connectored cable, and
technical literature. In addition,
ST connectored cables are
available for evaluation.
2
HFBR-0400 Series Part Number Guide
HFBR X4XXaa
1 = Transmitter
2 = Receiver
Option T (Threaded Port Option)
Option C (Conductive Port Receiver Option)
Option M (Metal Port Option)
4 = 820 nm Transmitter and
Receiver Products
2 = Tx, Standard Power
4 = Tx, High Power
2 = Rx, 5 MBd, TTL Output
6 = Rx, 125 MHz, Analog Output
0 = SMA, Housed
1 = ST, Housed
2 = FC, Housed
E = SC, Housed
Available Options
HFBR-1402
HFBR-1404
HFBR-1412
HFBR-1412T
HFBR-1414
HFBR-1414M
HFBR-1414T
HFBR-1424
HFBR-1412TM
HFBR-14E4
HFBR-2402
HFBR-2406
HFBR-2412TC
HFBR-2416
HFBR-2416M
HFBR-2412
HFBR-2412T
HFBR-2422
HFBR-24E6
HFBR-2416T
HFBR-2416TC
LINK SELECTION GUIDE
Data Rate (MBd)
5
5
20
32
55
125
155
160
Distance (m)
1500
2000
2700
2200
1400
700
600
500
Transmitter
HFBR-14X2
HFBR-14X4
HFBR-14X4
HFBR-14X4
HFBR-14X4
HFBR-14X4
HFBR-14X4
HFBR-14X4
Receiver
HFBR-24X2
HFBR-24X2
HFBR-24X6
HFBR-24X6
HFBR-24X6
HFBR-24X6
HFBR-24X6
HFBR-24X6
Fiber Size (µm)
200 HCS
62.5/125
62.5/125
62.5/125
62.5/125
62.5/125
62.5/125
62.5/125
Evaluation Kit
N/A
HFBR-0410
HFBR-0414
HFBR-0414
HFBR-0414
HFBR-0416
HFBR-0416
HFBR-0416
For additional information on specific links see the following individual link descriptions. Distances measured over temperature range
from 0 to 70°C.
Applications Support
Guide
This section gives the designer
information necessary to use the
HFBR-0400 series components to
make a functional fiber-optic
transceiver. Agilent offers a wide
selection of evaluation kits for
hands-on experience with fiberoptic products as well as a wide
Application Literature
Title
HFBR-0400 Series
Reliability Data
Application Bulletin 78
Application Note 1038
Application Note 1065
Application Note 1073
Application Note 1086
Application Note 1121
Application Note 1122
Application Note 1123
Application Note 1137
range of application notes complete with circuit diagrams and
board layouts. Furthermore,
Agilent’s application support
group is always ready to assist
with any design consideration.
Description
Transmitter & Receiver Reliability Data
Low Cost Fiber Optic Links for Digital Applications up to 155 MBd
Complete Fiber Solutions for IEEE 802.3 FOIRL, 10Base-FB and 10 Base-FL
Complete Solutions for IEEE 802.5J Fiber-Optic Token Ring
HFBR-0319 Test Fixture for 1X9 Fiber Optic Transceivers
Optical Fiber Interconnections in Telecommunication Products
DC to 32 MBd Fiber-Optic Solutions
2 to 70 MBd Fiber-Optic Solutions
20 to 160 MBd Fiber-Optic Solutions
Generic Printed Circuit Layout Rules
3
HFBR-0400 Series
Evaluation Kits
HFBR-0410 ST Evaluation Kit
Contains the following :
• One HFBR-1412 transmitter
• One HFBR-2412 five megabaud
TTL receiver
• Three meters of ST connectored 62.5/125 (µm fiber optic
cable with low cost plastic
ferrules.
• Related literature
HFBR-0414 ST Evaluation Kit
Includes additional components
to interface to the transmitter and
receiver as well as the PCB to
reduce design time.
Contains the following:
• One HFBR-1414T transmitter
• One HFBR-2416T receiver
• Three meters of ST connectored 62.5/125 µm fiber optic
cable
• Printed circuit board
• ML-4622 CP Data Quantizer
• 74ACTllOOON LED Driver
• LT1016CN8 Comparator
• 4.7 µH Inductor
• Related literature
HFBR-0400 SMA Evaluation
Kit
Contains the following :
• One HFBR-1402 transmitter
• One HFBR-2402 five megabaud
TTL receiver
• Two meters of SMA
connectored 1000 µm plastic
optical fiber
• Related literature
HFBR-0416 Evaluation Kit
Contains the following:
• One fully assembled 1x9
transceiver board for 155 MBd
evaluation including:
-HFBR-1414 transmitter
-HFBR-2416 receiver
-circuitry
• Related literature
Package and Handling
Information
Package Information
All HFBR-0400 Series
transmitters and receivers are
housed in a low-cost, dual-inline
package that is made of high
strength, heat resistant, chemically resistant, and UL 94V-O
flame retardant ULTEM® (plastic
(UL File #E121562). The
transmitters are easily identified
by the light grey color connector
port. The receivers are easily
identified by the dark grey color
connector port. (Black color for
conductive port.) The package is
designed for auto-insertion and
wave soldering so it is ideal for
high volume production
applications.
Handling and Design
Information
Each part comes with a protective
port cap or plug covering the
optics. These caps/plugs will vary
by port style. When soldering, it
is advisable to leave the protective cap on the unit to keep the
optics clean. Good system
performance requires clean port
optics and cable ferrules to avoid
obstructing the optical path.
Ultem® is a registered Trademark of the GE corporation.
Clean compressed air often is
sufficient to remove particles of
dirt; methanol on a cotton swab
also works well.
Recommended Chemicals for
Cleaning/Degreasing
HFBR-0400 Products
Alcohols: methyl, isopropyl,
isobutyl. Aliphatics: hexane,
heptane, Other: soap solution,
naphtha.
Do not use partially halogenated
hydrocarbons such as 1,1.1
trichloroethane, ketones such as
MEK, acetone, chloroform, ethyl
acetate, methylene dichloride,
phenol, methylene chloride, or
N-methylpyrolldone. Also, Agilent
does not recommend the use of
cleaners that use halogenated
hydrocarbons because of their
potential environmental harm.
4
Rx/Tx
COUNTRY OF
ORIGIN
A YYWW
HFBR-X40X
1/4 - 36 UNS 2A THREAD
Mechanical Dimensions
SMA Port
12.7
(0.50)
HFBR-X40X
22.2
(0.87)
6.35
(0.25)
12.7
(0.50)
6.4
(0.25)DIA.
3.81
(0.15)
3.6
(0.14)
5.1
(0.20)
1.27
(0.05)
5
6
4
2.54
(0.10)
8
2
7
3
PINS 2,3,6,7
0.46 DIA.
(0.018)
1
2.54
(0.10)
PINS 1,4,5,8
0.51 X 0.38
(0.020 X 0.015)
10.2
(0.40)
Mechanical Dimensions
ST Port
12.7
(0.50)
HFBR-X41X
Rx/Tx
COUNTRY OF
ORIGIN
A YYWW
HFBR-X41X
PIN NO. 1
INDICATOR
8.2
(0.32)
27.2
(1.07)
6.35
(0.25)
12.7
(0.50)
7.0 DIA.
(0.28)
3.81
(0.15)
5.1
(0.20)
1.27
(0.05)
5
2.54
(0.10)
8
2
7
6
4
PINS 2,3,6,7
0.46 DIA.
(0.018)
3
PINS 1,4,5,8
0.51 X 0.38
(0.020 X 0.015)
1
2.54
(0.10)
3.6
(0.14)
PIN NO. 1
INDICATOR
10.2
(0.40)
5
Mechanical Dimensions
Threaded ST Port
HFBR-X41XT
Rx/Tx
COUNTRY OF
ORIGIN
A YYWW
HFBR-X41XT
5.1
(0.20)
12.7
(0.50)
8.4
(0.33)
27.2
(1.07)
7.6
(0.30)
6.35
(0.25)
12.7
(0.50)
7.1 DIA.
(0.28)
3.6
(0.14)
5.1
(0.20)
3/8 - 32 UNEF - 2A
3.81
(0.15)
1.27
(0.05)
5
2.54
(0.10)
8
2
7
6
4
PINS 2,3,6,7
0.46 DIA.
(0.018)
3
PINS 1,4,5,8
0.51 X 0.38
(0.020 X 0.015)
1
2.54 DIA.
(0.10)
PIN NO. 1
INDICATOR
Mechanical Dimensions
FC Port
M8 x 0.75 6G
THREAD (METRIC)
12.7
(0.50)
Rx/Tx
COUNTRY OF
ORIGIN
A YYWW
HFBR-X42X
HFBR-X42X
19.6
(0.77)
12.7
(0.50)
7.9
(0.31)
3.81
(0.15)
2.5
(0.10)
5
6
8
1
2
7
3
4
2.5
(0.10)
PIN NO. 1
INDICATOR
3.6
(0.14)
5.1
(0.20)
10.2
(0.40)
10.2
(0.40)
6
Mechanical Dimensions
SC Port
Rx/Tx
COUNTRY OF
ORIGIN
A YYWW
HFBR-X4EX
HFBR-X4EX
28.65
(1.128)
6.35
(0.25)
12.7
(0.50)
10.0
(0.394)
10.38
(0.409)
3.60
(0.140)
5.1
(0.200)
15.95
(0.628)
3.81
(0.15)
1.27
(0.050)
2.54
(0.10)
2.54
(0.100)
12.7
(0.500)
7
LED OR DETECTOR IC
LENS–SPHERE
(ON TRANSMITTERS ONLY)
HOUSING
LENS–WINDOW
CONNECTOR PORT
HEADER
EPOXY BACKFILL
PORT GROUNDING PATH INSERT
Figure 1. HFBR-0400 ST Series Cross-Sectional View.
Panel Mount Hardware
HFBR-4401: for SMA Ports
HFBR-4411: for ST Ports
1/4 - 36 UNEF 2B THREAD
PART
NUMBER
3/8 - 32 UNEF 2B THREAD
0.2 IN.
7.87 DIA.
(0.310)
12.70 DIA.
(0.50)
1.65
(0.065)
HEX-NUT
HEX-NUT
1.65
(0.065)
3/8 - 32 UNEF 2A THREADING
1 THREAD
AVAILABLE
7.87 TYP.
(0.310) DIA.
6.61 DIA.
(0.260)
Rx/Tx
COUNTRY OF
ORIGIN
A YYWW
HFBR-X40X
DATE CODE
14.27 TYP.
(0.563) DIA.
10.41 MAX.
(0.410) DIA.
0.14
(0.005)
WASHER
0.46
(0.018)
WASHER
(Each HFBR-4401 and HFBR-4411 kit consists of 100 nuts and 100 washers.)
Port Cap Hardware
HFBR-4402: 500 SMA Port Caps
HFBR-4120: 500 ST Port Plugs (120 psi)
WALL
NUT
WASHER
8
Options
In addition to the various port
styles available for the HFBR0400 series products, there are
also several extra options that
can be ordered. To order an
option, simply place the corresponding option number at the
end of the part number. See page
2 for available options.
Option T (Threaded Port
Option)
• Allows ST style port components to be panel mounted.
• Compatible with all current
makes of ST multimode
connectors
• Mechanical dimensions are
compliant with MIL-STD83522/13
• Maximum wall thickness when
using nuts and washers from
the HFBR-4411 hardware kit is
2.8 mm (0.11 inch)
• Available on all ST ports
Option C (Conductive Port
Receiver Option)
• Designed to withstand electrostatic discharge (ESD) of 25kV
to the port
• Significantly reduces effect of
electromagnetic interference
(EMI) on receiver sensitivity
• Allows designer to separate the
signal and conductive port
grounds
• Recommended for use in noisy
environments
• Available on SMA and threaded
ST port style receivers only
Option M (Metal Port Option)
• Nickel plated aluminum connector receptacle
• Designed to withstand electrostatic discharge (ESD) of 15kV
to the port
• Significantly reduces effect of
electromagnetic interference
(EMI) on receiver sensitivity
• Allows designer to separate the
signal and metal port grounds
• Recommended for use in very
noisy environments
• Available on SMA, ST, and
threaded ST ports
9
Typical Link Data
HFBR-0400 Series
Description
The following technical data is
taken from 4 popular links using
the HFBR-0400 series: the 5 MBd
link, Ethernet 20 MBd link,
Token Ring 32 MBd link, and the
155 MBd link. The data given
corresponds to transceiver solutions combining the HFBR-0400
series components and various
recommended transceiver design
circuits using off-the-shelf
electrical components. This data
is meant to be regarded as an
example of typical link performance for a given design and does
not call out any link limitations.
Please refer to the appropriate
application note given for each
link to obtain more information.
5 MBd Link (HFBR-14XX/24X2)
Link Performance -40°C to +85°C unless otherwise specified
Parameter
Optical Power Budget
with 50/125 µm fiber
Optical Power Budget
with 62.5/125 µm fiber
Optical Power Budget
with 100/140 µm fiber
Optical Power Budget
with 200 µm fiber
Date Rate Synchronous
Asynchronous
Symbol
OPB50
Min.
4.2
Typ.
9.6
OPB62.5
8.0
15
dB
OPB100
8.0
15
dB
OPB200
12
20
dB
Propagation Delay
LOW to HIGH
Propagation Delay
HIGH to LOW
System Pulse Width
Distortion
Bit Error Rate
tPLH
72
ns
tPHL
46
ns
tPLH -tPHL
26
ns
dc
dc
BER
Max. Units
dB
5
2.5
10-9
Conditions
HFBR-14X4/24X2
NA = 0.2
HFBR-14X4/24X2
NA = 0.27
HFBR-14X2/24X2
NA = 0.30
HFBR-14X2/24X2
NA = 0.37
MBd
MBd
TA = 25°C,
PR = -21 dBm Peak
Reference
Note 1
Note 1
Note 1
Note 1
Note 2
Note 3,
Fig. 7
Figs. 6, 7, 8
Fiber cable
length = 1 m
Data Rate <5 Bd
PR > -24 dBm Peak
Notes:
1. OPB at TA = -40 to 85°C, VCC = 5.0 V dc, I F ON = 60 mA. PR = -24 dBm peak.
2. Synchronous data rate limit is based on these assumptions: a) 50% duty factor modulation, e.g., Manchester I or BiPhase
Manchester II; b) continuous data; c) PLL Phase Lock Loop demodulation; d) TTL threshold.
3. Asynchronous data rate limit is based on these assumptions: a) NRZ data; b) arbitrary timing-no duty factor restriction; c) TTL
threshold.
10
5 MBd Logic Link Design
If resistor R1 in Figure 2 is
70.4 Ω, a forward current IF of
48 mA is applied to the HFBR14X4 LED transmitter. With IF =
48 mA the HFBR-14X4/24X2
logic link is guaranteed to work
with 62.5/125 µm fiber optic
cable over the entire range of 0
to 1750 meters at a data rate of
dc to 5 MBd, with arbitrary data
format and pulse width distortion
typically less than 25%. By
setting R1 = 115 Ω, the transmitter can be driven with IF = 30 mA,
if it is desired to economize on
power or achieve lower pulse
distortion.
Figure 2. Typical Circuit Configuration.
The following example will illustrate the technique for selecting
the appropriate value of IF and R1.
Maximum distance required
= 400 meters. From Figure 3 the
drive current should be 15 mA.
From the transmitter data
VF = 1.5 V (max.) at IF = 15 mA
as shown in Figure 9.
VCC - VF
5 V - 1.5 V
R1 = –––––––
= –––––––––
IF
15 mA
R1 = 233 Ω
The curves in Figures 3, 4, and 5
are constructed assuming no inline splice or any additional
system loss. Should the link
consists of any in-line splices,
these curves can still be used to
calculate link limits provided they
are shifted by the additional
system loss expressed in dB. For
example, Figure 3 indicates that
with 48 mA of transmitter drive
current, a 1.75 km link distance
is achievable with 62.5/125 µm
fiber which has a maximum
attenuation of 4 dB/km. With
2 dB of additional system loss, a
1.25 km link distance is still
achievable.
Figure 3. HFBR-1414/HFBR-2412
Link Design Limits with 62.5/125 µm
Cable.
Figure 4. HFBR-14X2/HFBR-24X2
Link Design Limits with 100/140 µm
Cable.
55
70
65
tPLH (TYP) @ 25°C
60
55
50
45
40
tPHL (TYP) @ 25°C
35
30
50
tD – NRZ DISTORTION – ns
tPLH OR tPHL PROPOGATION DELAY –ns
75
45
40
35
30
25
25
20
-22 -21 -20 -19 -18 -17 -16 -15 -14 -13 -12
PR – RECEIVER POWER – dBm
Figure 6. Propagation Delay through
System with One Meter of Cable.
20
-22 -21 -20 -19 -18 -17 -16 -15 -14 -13 -12
PR – RECEIVER POWER – dBm
Figure 7. Typical Distortion of Pseudo
Random Data at 5 Mb/s.
Figure 8. System Propagation Delay Test Circuit and Waveform Timing Definitions.
0
60
-1
WORST CASE
-40°C, +85°C
UNDERDRIVE
-2
50
TYPICAL 26°C
UNDERDRIVE
-3
40
30
-4
CABLE ATTENUATION dB/km
α MAX (-40°C, +85°C)
4
α MIN (-40°C, +85°C)
1
α TYP (-40°C, +85°C)
2.8
-5
-6
0
0.4
0.8
1.2
1.6
2
LINK LENGTH (km)
Figure 5. HFBR-14X4/HFBR-24X2
Link Design Limits with 50/125 µm
Cable.
20
IF – TRANSMITTER FORWARD CURRENT – (mA)
10 LOG (t/to) NORMALIZED TRANSMITTER CURRENT (dB)
11
12
Ethernet 20 MBd Link (HFBR-14X4/24X6)
(refer to Application Note 1038 for details)
Typical Link Performance
Parameter
Receiver Sensitivity
Symbol
Link Jitter
Transmitter Jitter
Optical Power
LED rise time
LED fall time
Mean difference
Bit Error Rate
Output Eye Opening
Data Format 50% Duty Factor
PT
tr
tf
|tr - tf|
BER
Typ.[1,2]
-34.4
7.56
7.03
0.763
-15.2
1.30
3.08
1.77
10-10
36.7
20
Units
dBm
average
ns pk-pk
ns pk-pk
ns pk-pk
dBm
average
ns
ns
ns
ns
MBd
Conditions
20 MBd D2D2 Hexadecimal Data
2 km 62.5/125 µm fiber
ECL Out Receiver
TTL Out Receiver
20 MBd D2D2 Hexadecimal Data
20 MBd D2D2 Hexadecimal Data
Peak IF,ON = 60 mA
1 MHz Square Wave Input
At AUI Receiver Output
Notes:
1. Typical data at TA = 25°C, VCC = 5.0 V dc.
2. Typical performance of circuits shown in Figure 1 and Figure 3 of AN-1038 (see applications support section).
Token Ring 32 MBd Link (HFBR-14X4/24X6)
(refer to Application Note 1065 for details)
Typical Link Performance
Parameter
Receiver Sensitivity
Symbol
Link Jitter
Transmitter Jitter
Optical Power Logic Level “0”
Optical Power Logic Level “1”
LED Rise Time
LED Fall Time
Mean Difference
Bit Error Rate
Data Format 50% Duty Factor
PT ON
PT OFF
tr
tf
|tr - tf|
BER
Typ.[1,2]
-34.1
6.91
5.52
0.823
-12.2
-82.2
1.3
3.08
1.77
10-10
32
Units
dBm
average
ns pk-pk
ns pk-pk
ns pk-pk
dBm peak
nsec
nsec
nsec
Conditions
32 MBd D2D2 Hexadecimal Data
2 km 62.5/125 µm fiber
ECL Out Receiver
TTL Out Receiver
32 MBd D2D2 Hexadecimal Data
Transmitter TTL in IF ON = 60 mA,
IF OFF = 1 mA
1 MHz Square Wave Input
MBd
Notes:
1. Typical data at TA = 25°C, VCC = 5.0 V dc.
2. Typical performance of circuits shown in Figure 1 and Figure 3 of AN-1065 (see applications support section)
13
155 MBd Link (HFBR-14X4/24X6)
(refer to Application Bulletin 78 for details)
Typical Link Performance
Parameter
Symbol
Typ.[1,2]
Optical Power Budget
OPB50
7.9
with 50/125 µm fiber
Optical Power Budget
OPB62
11.7
with 62.5/125 µm fiber
Optical Power Budget
OPB100
11.7
with 100/140 µm fiber
Optical Power Budget
OPB200
16.0
with 200 µm HCSfFiber
Data Format 20% to
1
80% Duty Factor
System Pulse Width
|tPLH - tPHL|
Distortion
Bit Error Rate
BER
Units Max. Units Conditions
13.9
dB NA = 0.2
17.7
dB
NA = 0.27
17.7
dB
NA = 0.30
22.0
dB
NA = 0.35
175
1
10-9
Ref.
Note 2
MBd
ns
PR = -7 dBm Peak
1 meter 62.5/125 µm fiber
Data Rate < 100 MBaud
PR >-31 dBm Peak
Note 2
Notes:
1. Typical data at TA = 25°C, VCC = 5.0 V dc, PECL serial interface.
2. Typical OPB was determined at a probability of error (BER) of 10-9. Lower probabilities of error can be achieved with short fibers
that have less optical loss.
14
HFBR-14X2/14X4 LowCost High-Speed
Transmitters
Description
The HFBR-14XX fiber optic
transmitter contains an 820 nm
AlGaAs emitter capable of
efficiently launching optical
power into four different optical
fiber sizes: 50/125 µm, 62.5/125
µm, 100/140 µm, and 200 µm
HCS®. This allows the designer
flexibility in choosing the fiber
size. The HFBR-14XX is designed
to operate with the Agilent
HFBR-24XX fiber optic receivers.
The HFBR-14XX transmitter’s
high coupling efficiency allows
the emitter to be driven at low
current levels resulting in low
power consumption and increased
reliability of the transmitter. The
HFBR-14X4 high power transmitter is optimized for small size
fiber and typically can launch
-15.8 dBm optical power at
60 mA into 50/125 µm fiber and
-12 dBm into 62.5/125 µm fiber.
The HFBR-14X2 standard
transmitter typically can launch
-12 dBm of optical power at
60 mA into 100/140 µm fiber
cable. It is ideal for large size
fiber such as 100/140 µm. The
high launched optical power level
is useful for systems where star
couplers, taps, or inline connectors create large fixed losses.
Consistent coupling efficiency is
assured by the double-lens optical
system (Figure 1). Power coupled
into any of the three fiber types
varies less than 5 dB from part to
part at a given drive current and
temperature. Consistent coupling
efficiency reduces receiver
dynamic range requirements
which allows for longer link
lengths.
Housed Product
Unhoused Product
Absolute Maximum Ratings
Parameter
Storage Temperature
Operating Temperature
Lead Soldering Cycle
Forward Input Current
Reverse Input Voltage
Symbol
TS
TA
Temp.
Time
Peak
dc
IFPK
IFdc
VBR
Min.
-55
-40
Max.
+85
+85
+260
10
200
100
1.8
Units
°C
°C
°C
sec
mA
mA
V
Reference
Note 1
15
Electrical/Optical Specifications -40°C to +85°C unless otherwise specified.
Parameter
Forward Voltage
Symbol
VF
Forward Voltage
Temperature Coefficient
∆VF /∆T
Reverse Input Voltage
Peak Emission Wavelength
Diode Capacitance
Optical Power Temperature
Coefficient
VBR
λP
CT
∆PT /∆T
Thermal Resistance
14X2 Numerical Aperture
14X4 Numerical Aperture
14X2 Optical Port Diameter
14X4 Optical Port Diameter
θJA
NA
NA
D
D
Min.
1.48
1.8
792
Typ. [2] Max. Units
1.70
2.09
V
1.84
-0.22
mV/°C
-0.18
3.8
V
820
865
nm
55
pF
-0.006
dB/°C
-0.010
260
°C/W
0.49
0.31
290
µm
150
µm
IF
IF
IF
IF
IF
Conditions
= 60 mA dc
= 100 mA dc
= 60 mA dc
= 100 mA dc
= 100 µA dc
Reference
Figure 9
Figure 9
V = 0, f = 1 MHz
I = 60 mA dc
I = 100 mA dc
Notes 3, 8
Note 4
Note 4
HFBR-14X2 Output Power Measured Out of 1 Meter of Cable
Parameter
50/125 µm
Fiber Cable
NA = 0.2
Symbol
PT50
62.5/125 µm
Fiber Cable
NA = 0.275
PT62
100/140 µm
Fiber Cable
NA = 0.3
PT100
200 µm HCS
Fiber Cable
NA = 0.37
PT200
Min.
-21.8
-22.8
-20.3
-21.9
-19.0
-20.0
-17.5
-19.1
-15.0
16.0
-13.5
-15.1
-10.7
-11.7
-9.2
-10.8
Typ. [2]
-18.8
-16.8
-16.0
-14.0
-12.0
-10.0
-7.1
-5.2
Max.
-16.8
-15.8
-14.4
-13.8
-14.0
-13.0
-11.6
-11.0
-10.0
-9.0
-7.6
-7.0
-4.7
-3.7
-2.3
-1.7
Unit
dBm
peak
dBm
peak
dBm
peak
dBm
peak
Conditions
TA = 25°C IF = 60 mA dc
TA = 25°C
IF = 100 mA dc
TA = 25°C
IF = 60 mA dc
TA = 25°C
IF = 100 mA dc
TA = 25°C
IF = 60 mA dc
TA = 25°C
IF = 100 mA dc
TA = 25°C
IF = 60 mA dc
TA = 25°C
IF = 100 mA dc
Reference
Notes 5, 6, 9
CAUTION: The small junction sizes inherent to the design of these components increase the components’
susceptibility to damage from electrostatic discharge (ESD). It is advised that normal static precautions be
taken in handling and assembly of these components to prevent damage and/or degradation which may be
induced by ESD.
16
HFBR-14X4 Output Power Measured out of 1 Meter of Cable
Parameter
50/125 µm
Fiber Cable
NA = 0.2
Symbol
PT50
62.5/125 µm
Fiber Cable
NA = 0.275
PT62
100/140 µm
Fiber Cable
NA = 0.3
PT100
200 µm HCS
Fiber Cable
NA = 0.37
PT200
Min.
-18.8
-19.8
-17.3
-18.9
-15.0
-16.0
-13.5
-15.1
-9.5
-10.5
-8.0
-9.6
-5.2
-6.2
-3.7
-5.3
Typ.[2]
-15.8
-13.8
-12.0
-10.0
-6.5
-4.5
-3.7
-1.7
Max.
-13.8
-12.8
-11.4
-10.8
-10.0
-9.0
-7.6
-7.0
-4.5
-3.5
-2.1
-1.5
+0.8
+1.8
+3.2
+3.8
Unit
dBm
peak
dBm
peak
dBm
peak
dBm
peak
Conditions
TA = 25°C IF = 60 mA dc
TA = 25°C
IF = 100 mA dc
TA = 25°C
IF = 60 mA dc
TA = 25°C
IF = 100 mA dc
TA = 25°C
IF = 60 mA dc
TA = 25°C
IF = 100 mA dc
TA = 25°C
IF = 60 mA dc
TA = 25°C
IF = 100 mA dc
Reference
Notes 5, 6, 9
14X2/14X4 Dynamic Characteristics
Parameter
Rise Time, Fall Time
(10% to 90%)
Rise Time, Fall Time
(10% to 90%)
Pulse Width Distortion
Symbol
tr , tf
Min.
Typ. [2]
4.0
Max.
6.5
tr , tf
3.0
Units
nsec
No Pre-bias
nsec
PWD
0.5
nsec
Conditions
IF = 60 mA
Figure 12
IF = 10 to
100 mA
Reference
Note 7,
Note 7,
Figure 11
Figure 11
Notes:
1. For IFPK > 100 mA, the time duration should not exceed 2 ns.
2. Typical data at TA = 25°C.
3. Thermal resistance is measured with the transmitter coupled to a connector assembly and mounted on a printed circuit board.
4. D is measured at the plane of the fiber face and defines a diameter where the optical power density is within 10 dB of the
maximum.
5. PT is measured with a large area detector at the end of 1 meter of mode stripped cable, with an ST® precision ceramic ferrule (MILSTD-83522/13) for HFBR-1412/1414, and with an SMA 905 precision ceramic ferrule for HFBR-1402/1404.
6. When changing µW to dBm, the optical power is referenced to 1 mW (1000 µW). Optical Power P (dBm) = 10 log P (µW)/1000 µW.
7. Pre-bias is recommended if signal rate >10 MBd, see recommended drive circuit in Figure 11.
8. Pins 2, 6 and 7 are welded to the anode header connection to minimize the thermal resistance from junction to ambient. To further
reduce the thermal resistance, the anode trace should be made as large as is consistent with good RF circuit design.
9. Fiber NA is measured at the end of 2 meters of mode stripped fiber, using the far-field pattern. NA is defined as the sine of the half
angle,determined at 5% of the peak intensity point. When using other manufacturer’s fiber cable, results will vary due to differing
NA values and specification methods.
All HFBR-14XX LED transmitters are classified as IEC 825-1 Accessible Emission Limit (AEL)
Class 1 based upon the current proposed draft scheduled to go in to effect on January 1, 1997.
AEL Class 1 LED devices are considered eye safe. Contact your Agilent sales representative for
more information.
CAUTION: The small junction sizes inherent to the design of these components increase the components’
susceptibility to damage from electrostatic discharge (ESD). It is advised that normal static precautions be
taken in handling and assembly of these components to prevent damage and/or degradation which may be
induced by ESD.
17
Recommended Drive
Circuits
The circuit used to supply current
to the LED transmitter can
significantly influence the optical
switching characteristics of the
LED. The optical rise/fall times
and propagation delays can be
improved by using the appropriate circuit techniques. The
LED drive circuit shown in
Figure 11 uses frequency compensation to reduce the typical
rise/fall times of the LED and a
small pre-bias voltage to minimize
propagation delay differences
that cause pulse-width distortion.
The circuit will typically produce
rise/fall times of 3 ns, and a total
jitter including pulse-width distortion of less than 1 ns. This
circuit is recommended for applications requiring low edge jitter
(VCC - VF) + 3.97 (VCC - VF - 1.6 V)
R y = –––––––––––––––––––––––––––––––
IF ON (A)
1
R X1 = –
2
R
)
(––––
3.97
y
or high-speed data transmission
at signal rates of up to 155 MBd.
Component values for this circuit
can be calculated for different
LED drive currents using the
equations shown below. For
additional details about LED
drive circuits, the reader is
encouraged to read Agilent
Application Bulletin 78 and
Application Note 1038.
(5 - 1.84) + 3.97 (5 - 1.84 - 1.6)
R y = –––––––––––––––––––––––––––––
0.100
3.16 + 6.19
R y = ––––––––––– = 93.5 Ω
0.100
93.5
) = 11.8 Ω
(––––
3.97
R EQ2(Ω) = R X1 - 1
1
R X1 = –
2
R X2 = R X3 = R X4 = 3(REQ2)
R EQ2 = 11.8 - 1 = 10.8 Ω
2000(ps)
C(pF) = ––––––––
RX1(Ω)
R X2 = R X3 = R X4 = 3(10.8) = 32.4 Ω
Example for I F ON = 100 mA: VF can be
obtained from Figure 9 (= 1.84 V).
2000 ps
C = ––––––– = 169 pF
11.8 Ω
2.0
3.0
1.8
1.6
2.0
1.4
1.2
1.4
1.0
0.8
1.0
0
0.8
-1.0
0.6
-2.0
-3.0
-4.0
-5.0
-7.0
0.4
0.2
0
0 10 20 30 40 50 60 70 80 90 100
IF – FORWARD CURRENT – mA
Figure 9. Forward Voltage and
Current Characteristics.
Figure 10. Normalized Transmitter
Output vs. Forward Current.
Figure 11. Recommended Drive Circuit.
Figure 12. Test Circuit for Measuring tr, t f.
P(IF) – P(60 mA) – RELATIVE POWER RATIO – dB
P(IF) – P(60 mA) – RELATIVE POWER RATIO
18
19
HFBR-24X2 Low-Cost
5 MBd Receiver
Description
The HFBR-24X2 fiber optic
receiver is designed to operate
with the Hewlett-Packard HFBR14XX fiber optic transmitter and
50/125 µm, 62.5/125 µm, 100/
140 µm, and 200 µm HCS® fiber
optic cable. Consistent coupling
into the receiver is assured by the
lensed optical system (Figure 1).
Response does not vary with fiber
size ≤ 0.100 µm.
The HFBR-24X2 receiver incorporates an integrated photo IC
containing a photodetector and
dc amplifier driving an opencollector Schottky output
transistor. The HFBR-24X2 is
designed for direct interfacing to
popular logic families. The
absence of an internal pull-up
resistor allows the open-collector
output to be used with logic
families such as CMOS requiring
voltage excursions much higher
than VCC.
Housed Product
Both the open-collector “Data”
output Pin 6 and VCC Pin 2 are
referenced to “Com” Pin 3, 7. The
“Data” output allows busing,
strobing and wired “OR” circuit
configurations. The transmitter is
designed to operate from a single
+5 V supply. It is essential that a
bypass capacitor (0.1 µF
ceramic) be connected from
Pin 2 (VCC) to Pin 3 (circuit
common) of the receiver.
Unhoused Product
PIN
1
2
3
4
FUNCTION
VCC (5 V)
COMMON
DATA
COMMON
Absolute Maximum Ratings
Parameter
Storage Temperature
Operating Temperature
Lead Soldering Cycle
Symbol
TS
TA
Min.
-55
-40
Temp.
Time
Supply Voltage
Output Current
Output Voltage
Output Collector Power Dissipation
Fan Out (TTL)
VCC
IO
VO
PO AV
N
-0.5
-0.5
Max.
+85
+85
+260
10
7.0
25
18.0
40
5
Units
°C
°C
°C
sec
V
mA
V
mW
Reference
Note 1
Note 2
20
Electrical/Optical Characteristics -40°C to + 85°C unless otherwise specified
Fiber sizes with core diameter ≤ 100 µm and NA ≤ 0.35, 4.75 V ≤ VCC ≤ 5.25 V
Typ.[3]
5
Max.
250
Units
µA
VOL
0.4
0.5
V
High Level Supply Current
ICCH
3.5
6.3
mA
Low Level Supply Current
ICCL
6.2
10
mA
Equivalent N.A.
Optical Port Diameter
NA
D
0.50
400
Parameter
High Level Output Current
Symbol
IOH
Low Level Output Voltage
Min.
Conditions
VO = 18
PR < -40 dBm
IO = 8 mA
PR > -24 dBm
VCC = 5.25 V
PR < -40 dBm
VCC = 5.25 V
PR > -24 dBm
µm
Reference
Note 4
Dynamic Characteristics
-40°C to +85°C unless otherwise specified; 4.75 V ≤ VCC ≤ 5.25 V; BER ≤ 10-9
Parameter
Peak Optical Input Power
Logic Level HIGH
Peak Optical Input Power
Logic Level LOW
Propagation Delay LOW
to HIGH
Propagation Delay HIGH
to LOW
Symbol
PRH
Min.
P RL
-25.4
2.9
-24.0
4.0
Typ.[3]
Max.
-40
0.1
-9.2
120
-10.0
100
tPLHR
65
Units
dBm pk
µW pk
dBm pk
µW pk
dBm pk
µW pk
ns
tPHLR
49
ns
Conditions
λP = 820 nm
Reference
Note 5
TA = +25°C,
IOL = 8 mA
Note 5
IOL = 8 mA
TA = 25°C,
PR = -21 dBm,
Data Rate =
5 MBd
Note 6
Notes:
1. 2.0 mm from where leads enter case.
2. 8 mA load (5 x 1.6 mA), R L = 560 Ω.
3. Typical data at T A = 25°C, VCC = 5.0 Vdc.
4. D is the effective diameter of the detector image on the plane of the fiber face. The numerical value is the product of the actual
detector diameter and the lens magnification.
5. Measured at the end of 100/140 µm fiber optic cable with large area detector.
6. Propagation delay through the system is the result of several sequentially-occurring phenomena. Consequently it is a combination
of data-rate-limiting effects and of transmission-time effects. Because of this, the data-rate limit of the system must be described in
terms of time differentials between delays imposed on falling and rising edges.
7. As the cable length is increased, the propagation delays increase at 5 ns per meter of length. Data rate, as limited by pulse width
distortion, is not affected by increasing cable length if the optical power level at the receiver is maintained.
CAUTION: The small junction sizes inherent to the design of these components increase the components’
susceptibility to damage from electrostatic discharge (ESD). It is advised that normal static precautions be
taken in handling and assembly of these components to prevent damage and/or degradation which may be
induced by ESD.
21
HFBR-24X6 Low-Cost
125 MHz Receiver
Description
The HFBR-24X6 fiber optic
receiver is designed to operate
with the Agilent HFBR-14XX
fiber optic transmitters and 50/
125 µm, 62.5/125 µm, 100/140
µm and 200 µm HCS® fiber optic
cable. Consistent coupling into
the receiver is assured by the
lensed optical system (Figure 1).
Response does not vary with fiber
size for core diameters of 100 µm
or less.
The receiver output is an analog
signal which allows follow-on
circuitry to be optimized for a
variety of distance/data rate
requirements. Low-cost external
components can be used to convert
the analog output to logic
compatible signal levels for various
data formats and data rates up to
175 MBd. This distance/data rate
tradeoff results in increased optical
power budget at lower data rates
which can be used for additional
distance or splices.
The HFBR-24X6 receiver contains
a PIN photodiode and low noise
transimpedance pre-amplifier
integrated circuit. The HFBR-24X6
receives an optical signal and
converts it to an analog voltage.
The output is a buffered emitterfollower. Because the signal
amplitude from the HFBR-24X6
receiver is much larger than from a
simple PIN photodiode, it is less
susceptible to EMI, especially at
high signaling rates. For very noisy
environments, the conductive or
metal port option is recommended.
A receiver dynamic range of 23 dB
over temperature is achievable
(assuming 10-9 BER).
receiver from noisy host systems.
Refer to AN 1038, 1065, or AB 78
for details.
Housed Product
6
VCC
2
ANALOG
SIGNAL
3&7
4
5
3
6
2
1
7
VEE
8
BOTTOM VIEW
The frequency response is typically
dc to 125 MHz. Although the
HFBR-24X6 is an analog receiver,
it is compatible with digital
systems. Please refer to
Application Bulletin 78 for simple
and inexpensive circuits that
operate at 155 MBd or higher.
The recommended ac coupled
receiver circuit is shown in Figure
12. It is essential that a 10 ohm
resistor be connected between pin
6 and the power supply, and a 0.1
µF ceramic bypass capacitor be
connected between the power
supply and ground. In addition, pin
6 should be filtered to protect the
PIN NO. 1
INDICATOR
PINFUNCTION
1†
N.C.
2
SIGNAL
3*
VEE
4†
N.C.
5†
N.C.
6
VCC
7*
VEE
8†
N.C.
* PINS 3 AND 7 ARE ELECTRICALLY
CONNECTED TO THE HEADER.
† PINS 1, 4, 5, AND 8 ARE ISOLATED FROM
THE INTERNAL CIRCUITRY, BUT ARE
ELECTRICALLY CONNECTED TO EACH OTHER.
Unhoused Product
PIN
1
2*
3
4*
FUNCTION
SIGNAL
VEE
VCC
VEE
6
BIAS & FILTER
CIRCUITS
VCC
POSITIVE
SUPPLY
300 pF
2
VOUT
ANALOG
SIGNAL
5.0
mA
3, 7
VEE
NEGATIVE
SUPPLY
Figure 11. Simplified Schematic Diagram.
CAUTION: The small junction sizes inherent to the design of these components increase the components’
susceptibility to damage from electrostatic discharge (ESD). It is advised that normal static precautions be
taken in handling and assembly of these components to prevent damage and/or degradation which may be
induced by ESD.
22
Absolute Maximum Ratings
Parameter
Storage Temperature
Operating Temperature
Lead Soldering Cycle
Symbol
TS
TA
Min.
-55
-40
Max.
+85
+85
+260
10
6.0
25
VCC
Temp.
Time
Supply Voltage
Output Current
Signal Pin Voltage
VCC
IO
VSIG
-0.5
-0.5
Units
°C
°C
°C
s
V
mA
V
Reference
Note 1
Electrical/Optical Characteristics -40°C to +85°C; 4.75 V ≤ Supply Voltage ≤ 5.25 V,
RLOAD = 511 Ω, Fiber sizes with core diameter ≤ 100 µm, and N.A. ≤ -0.35 unless otherwise specified
Parameter
Responsivity
Symbol
RP
Min.
5.3
Typ. [2]
7
Max.
9.6
Units
mV/µW
0.40
11.5
0.59
mV/µW
mV
0.70
mV
-43.0
-41.4
dBm
0.050
0.065
4.5
RMS Output Noise
Voltage
VNO
Equivalent Input
Optical Noise Power
(RMS)
Optical Input Power
(Overdrive)
PN
Output Impedance
Zo
dc Output Voltage
Power Supply Current
Equivalent N.A.
Equivalent Diameter
PR
Vo dc
IEE
NA
D
-7.6
175
-8.2
150
30
-4.2
-3.1
9
0.35
324
-2.4
15
Conditions
Reference
TA= 25°C
Note 3, 4
@ 820 nm, 50 MHz
Figure 16
@ 820 nm, 50 MHz
Bandwidth Filtered
Note 5
@ 75 MHz
PR = 0 µW
Unfiltered Bandwidth Figure 13
PR = 0 µW
Bandwidth Filtered
@ 75 MHz
µW
dBm pk TA = 25°C
µW pk
dBm pk
µW pk
Ω
Test Frequency =
50 MHz
V
PR = 0 µW
mA
RLOAD = 510 Ω
µm
Figure 14
Note 6
Note 7
CAUTION: The small junction sizes inherent to the design of these components increase the components’
susceptibility to damage from electrostatic discharge (ESD). It is advised that normal static precautions be
taken in handling and assembly of these components to prevent damage and/or degradation which may be
induced by ESD.
23
Dynamic Characteristics -40°C to +85°C; 4.75 V ≤ Supply Voltage ≤ 5.25 V; RLOAD = 511 Ω, CLOAD
= 5 pF unless otherwise specified
Parameter
Rise/Fall Time
10% to 90%
Pulse Width Distortion
Symbol
tr, tf
Min. Typ. [2]
3.3
PWD
Units
ns
Conditions
PR = 100 µW peak
Reference
Figure 15
2.5
ns
PR = 150 µW peak
2
%
125
0.41
MHz
Hz • s
PR = 5 µW peak,
tr = 1.5 ns
-3 dB Electrical
Note 8,
Figure 14
Note 9
0.4
Overshoot
Bandwidth (Electrical)
Bandwidth - Rise
Time Product
Max.
6.3
BW
Note 10
Notes:
1. 2.0 mm from where leads enter case.
2. Typical specifications are for operation at TA = 25°C and VCC = +5 V dc.
3. For 200 µm HCS fibers, typical responsivity will be 6 mV/µW. Other parameters will change as well.
4. Pin #2 should be ac coupled to a load ≥ 510 ohm. Load capacitance must be less than 5 pF.
5. Measured with a 3 pole Bessel filter with a 75 MHz, -3 dB bandwidth. Recommended receiver filters for various bandwidths are
provided in Application Bulletin 78.
6. Overdrive is defined at PWD = 2.5 ns.
7. D is the effective diameter of the detector image on the plane of the fiber face. The numerical value is the product of the actual
detector diameter and the lens magnification.
8. Measured with a 10 ns pulse width, 50% duty cycle, at the 50% amplitude point of the waveform.
9. Percent overshoot is defined as:
VPK - V100%
––––––––––
x 100%
V100%
10. The conversion factor for the rise time to bandwidth is 0.41 since the HFBR-24X6 has a second order bandwidth limiting
characteristic.
(
)
0.1 µF
+5 V
10 Ω
6
30 pF
2
3&7
POST
AMP
LOGIC
OUTPUT
RLOADS
500 Ω MIN.
Figure 12. Recommended ac Coupled Receiver Circuit. (See AB 78 and AN 1038 for more information.)
CAUTION: The small junction sizes inherent to the design of these components increase the components’
susceptibility to damage from electrostatic discharge (ESD). It is advised that normal static precautions be
taken in handling and assembly of these components to prevent damage and/or degradation which may be
induced by ESD.
3.0
125
100
75
50
25
0
6.0
2.5
tr, tf – RESPONSE TIME – ns
SPECTRAL NOISE DENSITY – nV/
HZ
PWD – PULSE WIDTH DISTORTION – ns
150
2.0
1.5
1.0
0.5
0
0
50
100
150
200
250
300
FREQUENCY – MHZ
Figure 13. Typical Spectral Noise
Density vs. Frequency.
0
10
20
30
40
50
60
70
PR – INPUT OPTICAL POWER – µW
Figure 14. Typical Pulse Width
Distortion vs. Peak Input Power.
80
5.0
4.0
tf
3.0
tr
2.0
1.0
-60
-40
-20
0
20
40
60
80
100
TEMPERATURE – °C
Figure 15. Typical Rise and Fall
Times vs. Temperature.
NORMALIZED RESPONSE
1.25
1.00
0.75
0.50
0.25
0
400
480
560
640
720
800
880 960 1040
λ – WAVELENGTH – nm
Figure 16. Receiver Spectral
Response Normalized to 820 nm.
www.semiconductor.agilent.com
Data subject to change.
Copyright © 2001 Agilent Technologies, Inc.
October 29, 2001
Obsoletes 5980-1065E (8/00)
5988-3624EN