HFBR-59L1AL_技术文档

Agilent HFBR-59L1AL 1.25 GBd Ethernet

and 1.0625 GBd Fibre Channel 850 nm

SFF Low Voltage (3.3 V) Optical

Transceiver

Data Sheet

Features

• Data rate specification:

1.25 GBd operation for IEEE 802.3

Gigabit Ethernet 1000BASE-SX

1.0625 GBd operation for FC-PI

100-M5-SN-I and FC-PI 100-M6-

SN-I

Description

The HFBR-59L1AL from Agilent

Technologies is a high

performance, cost-effective

optical transceiver for serial

optical data communications

applications operating at

1.25 Gb/s and 1.0625 Gb/s. This

module is designed for

multimode fiber and operates at

a nominal wavelength of 850 nm.

The transceiver incorporates

3.3 V DC compatible technology

including an 850 nm VCSEL

transmitter. The HFBR-59L1AL

offers maximum flexibility to

Fibre Channel and Ethernet

designers, manufacturers, and

system integrators. It is

designed for use in short reach

multimode fiber optic

1000BASE-SX and Fiber

Channel (100-M5-SN-1) links.

This device is also designed for a

wide voltage and temperature

range of operation.

• Wide temperature and supply

voltage operation

Related Products

• Industry standard 2 x 5 SFF

package

• LC-duplex connector optical

interface

• Link lengths at 1.25 GBd:

0.5 to 500 m – 50/125 mm MMF

0.5 to 275 m – 62.5/125 mm MMF

• Link lengths at 1.0625 GBd:

0.5 to 500 m – 50/125 mm MMF

0.5 to 300 m – 62.5/125 mm MMF

• Reliable 850 nm Vertical Cavity

Surface Emitting Laser (VCSEL)

source technology

•

HFCT-59L1ATL: 1300 nm Small

Form Factor optical transceiver

for 10 km Gigabit Ethernet links

HFBR-5911L/AL: 850 nm Small

Form Factor optical transceiver

for short reach Gigabit Ethernet

(1000BASE-SX) links

•

HFBR-5701L/LP: 850 nm Small

Form Factor Pluggable optical

transceiver for short reach

Gigabit Ethernet (1000BASE-SX)

and 1.0625 Gbd Fibre Channel

links

•

HDMP-2634: Single SerDes IC

2.5/1.25 Gigabit

HDMP-1687: Quad SerDes IC for

Gigabit Ethernet with 10 bit

parallel interface and TTL clock

input

• Laser AEL Class I (eye safe) per:

US 21 CFR (J)

EN 60825-1 (+All)

• Single +3.3 V power supply

operation

• Wave solder and aqueous wash

process compatible

•

HDMP-1685A: Quad SerDes IC for

Gigabit Ethernet with 5 bit

parallel interface and DDR TTL

clock input

HDMP-1636A/46A: Single SerDes

IC for Gigabit Ethernet and Fiber

Channel

This transceiver is compliant

with the Small Form Factor

Multi-Source Agreement and is

fully compliant with all

equipment meeting the Gigabit

Ethernet (1000 Base-SX) and

Fibre Channel (FC-PI 100-M5-

SN-I, FC-PI 100-M6-SN-I, FC-PH2

100-M5-SN and FC-PH2 100-M6-

SN-I 1.0625 GBd) specifications.

Applications

• Short reach Gigabit Ethernet links

• High speed backplane

interconnects

• Switched backbones

• iSCSI applications

• Mass storage system I/O

• Computer system I/O

• High speed peripheral interface

• High speed switching systems

• Host adaptor I/O

•

HDMP-1637A: Single SerDes IC

with PECL RefClk

HDMP-1638: Single SerDes IC

with PECL RefClk and Dual Serial

I/O

HFBR-59L1AL BLOCK DIAGRAM

LIGHT FROM FIBER

RECEIVER

ELECTRICAL INTERFACE

RD+ (RECEIVE DATA)

RD– (RECEIVE DATA)

SIGNAL DETECT

AMPLIFICATION

& QUANTIZATION

PHOTO-DETECTOR

OPTICAL INTERFACE

LIGHT TO FIBER

TRANSMITTER

VCSEL

Tx_DISABLE

LASER

DRIVER &

SAFETY

TD+ (TRANSMIT DATA)

TD– (TRANSMIT DATA)

CIRCUITRY

Figure 1. Transceiver functional diagram. (See Process Compatibility Specifications).

Module Package

Agilent offers the Pin Through

Hole package utilizing an

Pin Description

Pin Name

6

7

8

9

10

5

4

3

2

1

integral LC Duplex optical

interface connector. The

transceiver uses a reliable 850

nm VCSEL source and requires a

3.3 V dc power supply for

optimal system design.

Type

1

2

3

4

5

6

7

8

9

10

RX Ground

Ground

RX Power

RX SD

Power

Status Out

Signal Out

Power

Module Diagrams

Figure 1 illustrates the major

functional components of the

HFBR-59L1AL. The connection

diagram for both modules are

shown in Figure 2. Figures 6a

and 6b depict the external

configuration and dimensions of

the module.

RX Dara Bar

RX Data

TX Power

TX Ground

TX Disable

TX Data

TX

RX

Ground

Control In

Signal In

Installation

The HFBR-59L1AL can be

installed in any MSA compliant

Pin Through Hole port. The

module Pin Description is

shown in Figure 2.

TOP VIEW

TX Data Bar

Figure 2. Module pin assignments and pin configuration.

Recommended Solder Fluxes

Solder fluxes used with the

HFBR-59L1AL should be

watersoluble, organic fluxes.

Recommended solder fluxes

include Lonco 3355-11 from

London Chemical West, Inc. of

Burbank, CA, and 100 Flux from

Alpha-Metals of Jersey City, NJ.

Recommended Cleaning/Degreasing

Chemicals

Alcohols: methyl, isopropyl,

isobutyl.

Aliphatics: hexane, heptane.

Other: naphtha. Do not use

partially halogenated

hydrocarbons such as 1,1.1

trichoroethane or ketones such

as MEK, acetone, chloroform,

ethyl acetate, methylene

dichloride, phenol, methylene

chloride, or N-methylpyrolldone.

Solder and Wash Process Capability

These transceivers are delivered

with protective process plugs

inserted into the LC 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

industry standard wave or hand

solder processes.

2

Also, Agilent does not

recommend the use of cleaners

that use halogenated

hydrocarbons because of their

potential environmental harm.

Signal Detect

Electrostatic Discharge (ESD)

There are two conditions in

which immunity to ESD damage

is important. Table 1 documents

our immunity to both of these

conditions. The first condition

is during handling of the

transceiver prior to attachment

to the PCB. To protect the

transceiver, it is important to

use normal ESD handling

precautions. These precautions

include using grounded wrist

straps, work benches, and floor

mats in ESD controlled areas.

The ESD sensitivity of the

HFBR-59L1AL is compatible

with typical industry production

environments. The second

condition is static discharges to

the exterior of the host

The Signal Detect (SD) output

indicates if the optical input

signal to the receiver does not

meet the minimum detectable

level for Fibre Channel

compliant signals. When SD is

low it indicates loss of signal.

When SD is high it indicates

normal operation. The Signal

Detect thresholds are set to

indicate a definite optical fault

has occurred (e.g., disconnected

or broken fiber connection to

receiver, failed transmitter).

Transmitter Section

The transmitter section includes

an 850 nm VCSEL (Vertical

Cavity Surface Emitting Laser)

light source and a transmitter

driver circuit. The driver circuit

maintains a constant optical

power level provided that the

data pattern is valid 8B/10B

code. Connection to the

transmitter is provided via an

LC optical connector.

Functional Data I/O

Agilent’s HFBR-59L1AL fiber-

optic transceiver is designed to

accept industry standard

differential signals. In order to

reduce the number of passive

components required on the

customer’s board, Agilent has

included the functionality of the

transmitter bias resistors and

coupling capacitors within the

fiber optic module. The

transceiver is compatible with

an “ac-coupled” configuration

and is internally terminated.

Figure 1 depicts the functional

diagram of the HFBR-59L1AL.

Caution should be taken to

account for the proper

TX Disable

The HFBR-59L1AL accepts a

LVTTL transmit disable control

signal input which shuts down

the transmitter. A high signal

implements this function while a

low signal allows normal laser

operation. In the event of a fault

(e.g., eye safety circuit

activated), cycling this control

signal resets the module. The

TX Disable control should be

actuated upon initialization of

the module. See Figure 5 for

product timing diagrams.

equipment chassis after

installation. To the extent that

the duplex LC optical interface

is exposed to the outside of the

host equipment chassis, it may

be subject to system-level ESD

requirements. The ESD

performance of the HFBR-

59L1AL exceeds typical industry

standards.

Immunity

Equipment hosting the HFBR-

59L1AL modules will be

subjected to radio-frequency

electromagnetic fields in some

environments. The transceivers

have good immunity to such

fields due to their shielded

design.

Eye Safety Circuit

interconnection between the

supporting Physical Layer

integrated circuits and the

HFBR-59L1AL. Figure 3

illustrates the recommended

interface circuit.

For an optical transmitter

device to be eye-safe in the event

of a single fault failure, the

transmitter will either maintain

normal, eye-safe operation or be

disabled. In the event of an eye

safety fault, the VCSEL will be

disabled.

Reference Designs

Electromagnetic Interference (EMI)

Most equipment designs utilizing

these high-speed transceivers

from Agilent Technologies will

Figure 3 depicts a typical

application configuration, while

Figure 4 depicts the

multisourced power supply filter be required to meet the

circuit design.

Receiver Section

Connection to the receiver is

provided via an LC optical

connector. The receiver circuit

also includes a Signal Detect

(SD) circuit which provides an

open collector logic low output

in the absence of a usable input

optical signal level.

requirements of FCC in the

United States, CENELEC

Regulatory Compliance

See Table 1 for transceiver

Regulatory Compliance

performance. The overall

equipment design will determine

the certification level. The

transceiver performance is

offered as a figure of merit to

assist the designer.

EN55022 (CISPR 22) in Europe

and VCCI in Japan. The metal

housing and shielded design of

the HFBR-59L1AL minimize the

EMI challenge facing the host

equipment designer.

3

These transceivers provide

superior EMI performance. This

greatly assists the designer in

the management of the overall

system EMI performance.

Caution

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.

There are no user serviceable

parts nor is any maintenance

required for the HFBR-59L1AL.

All adjustments are made at the

factory before shipment to our

customers.

Eye Safety

These 850 nm VCSEL-based

transceivers provide Class 1 eye

safety by design. Agilent has

tested the transceiver design for

compliance with the

Ordering Information

Tampering with or modifying the Please contact your local field

performance of the HFBR-

59L1AL will result in voided

product warranty. It may also

result in improper operation of

sales engineer or one of Agilent

Technologies franchised

distributors for ordering

information. For technical

requirements listed in Table 1:

Regulatory Compliance, under

the HFBR-59L1AL circuitry, and information regarding this

normal operating conditions and possible overstress of the laser

product, including the MSA,

please visit Agilent Technologies

Semiconductors Products

under a single fault condition.

source. Device degradation or

product failure may result.

Connection of the HFBR-59L1AL Website at www.agilent.com/

Flammability

The HFBR-59L1AL VCSEL

transceiver housing is made of

metal and high strength, heat

resistant, chemically resistant,

and UL 94V-0 flame retardant

plastic.

to a non-approved optical

source, operating above the

recommended absolute

maximum conditions or

view/fiber. Use the quick search

feature to search for this part

number. You may also contact

Agilent Technologies

operating the HFBR-59L1AL in a Semiconductor Products

manner inconsistent with its

design and function may result

in hazardous radiation exposure

and may be considered an act of

modifying or manufacturing a

laser product.

Customer Response Center at

1-800-235-0312.

Table 1. Regulatory Compliance

Feature

Test Method

Performance

Electrostatic Discharge (ESD) to the

Electrical Pins

MIL-STD-883C

Method 3015.4

Class 2 (>2000 V)

Electrostatic Discharge (ESD) to the

Duplex LC Receptacle

Variation of IEC 61000-4-2

Typically withstand at least 25 kV without damage when the

duplex LC connector receptacle is contaced by a Human

Body Model probe.

Electromagnetic Interference (EMI)

FCC Class B

CENELEC EN55022 Class B

(CISPR 22A)

System margins are dependent on customer board and

chassis design.

VCCI Class 1

Immunity

Variation of IEC 61000-4-3

Typically shows a negligible effect from a 10 V/m field

swept from 80 to 1000 MHz applied to the transceiver

without a chassis enclosure.

Eye Safety

US FDA CDRH AEL Class 1

En(IEC)60825-1, 2

CDRH file # 9720151

TUV file # R2079009

EN60950 Class 1

Component Recognition

Underwriters Laboratories and Canadian

Standards Association Joint Component

Recognition for Information Technology

Equipment including Electrical Business

Equipment.

UL file # E173874

4

1 µH

3.3 V

10 µF

0.1 µF

V

,T

CC

0.1 µF

9.0 K

Tx_DISABLE

TD+

GP04

0.01 µF

50 Ω

VREFR

TX[0:9]

SO+

LASER DRIVER

& SAFETY

CIRCUITRY

100 Ω

TD–

TX GND

SO–

TBC

EWRAP

TBC

EWRAP

0.01 µF

HDMP-1687

V

,R

CC

50 Ω

or

0.1

µF

PROTOCOL

IC

10 µF

HDMP-1636A

RX[0:9]

0.01 µF

RD+

50 Ω

SI+

SI–

RBC

Rx_RATE

RBC

100 Ω

AMPLIFICATION

Rx_RATE

RD–

&

REFCLK

QUANTIZATION

Rx_SD

1.2 K

RX GND

50 Ω

,R

V

,R

CC

V

CC

HFBR-59L1AL

REFCLK

106.25 MHz

Figure 3. Typical application configuration.

1 µH

V

T

CC

0.1 µF

3.3 V

V

CC

R

10 µF

0.1 µF

10 µF

SFF MODULE

HOST BOARD

NOTE: INDUCTORS MUST HAVE LESS THAN 1Ω SERIES RESISTANCE PER MSA.

Figure 4. MSA recommended power supply filter.

5

Table 2. Pin Description

Name

Function/Description

MSA Notes

1

V_EER

Receiver Ground

1

2

3

V

_CCR

Receiver Power: 3.3 V 10%

Signal Detect: Low indicates Loss of Signal

Inverse Received Data Out

Received Data Out

5

3

4

5

1

2

SD

4

RD-

RD+

5

6

V

_CCT

Transmitter Power: 3.3V 10%

Transmitter Ground

7

V_EET

8

TX Disable

TD+

Transmitter Disable: Module disables on High

Transmitter Data In

9

10

TD-

Inverse Transmitter Data In

Notes:

1. Transmitter and Receiver Ground are common in the internal module PCB. They are electrically connected to signal ground within the module, and to

the housing shield (see Note 5 in Figure 7c). This housing shield is electrically isolated from the nose shield which is connected to chassis ground

(see Note 4 in Figure 7c).

2. TX disable input is used to shut down the laser output per the state table below. It is pulled down internally within the module with a 9.0 KW resistor.

Low (0 – 0.8 V):

Between (0.8 V and 2.0 V):

High (2.0 – 3.465 V):

Open:

Transmitter on

Undefined

Transmitter Disabled

TransmitterEnabled

3. SD (Signal Detect) is a normally high LVTTL output. When high it indicates that the received optical power is adequate for normal operation. When

Low, it indicates that the received optical power is below the worst case receiver sensitivity, a fault has occurred, and the link is no longer valid.

4. RD-/+: These are the differential receiver outputs. They are ac coupled 100 W differential lines which should be terminated with 100 W differential at

the user SerDes. The ac coupling is done inside the module and is thus not required on the host board. The voltage swing on these lines will be

between 400 and 2000 mV differential (200 – 1000 mV single ended) when properly terminated. These levels are compatible with CML and LVPECL

voltage swings.

5.

V R and V T are the receiver and transmitter power supplies. They are defined as 2.97 – 3.63 V at the PTH connector pin. The maximum supply

CC CC

current is 200 mA.

6

Absolute Maximum Ratings

Parameter

Symbol

Minimum

Typical

Maximum

Unit

°C

%

Notes

Storage Temperature

Case Temperature

Relative Humidity

Supply Voltage

T_S

-40

-10

5

+100

+85

95

1

T_C

1, 2

1

RH

V_CCT, R

V_I

-0. 5

-0.5

4

V

1, 2

1

Data/Control Input Voltage

V_CC+ 0.3

5.0

V

Sense Output Current

Signal Detect [SD]

I_D

mA

1

Notes:

1. Absolute Maximum Ratings are those values beyond which damage to the device may occur if these limits are exceeded for other than a short period

of time. See Reliability Data Sheets 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.

Recommended Operating Conditions

Parameter

Symbol

T_C

Minimum

-10

Typical

+25

Maximum

+85

Unit

°C

Notes

Case Temperature

Module Supply Voltage

1

V_CCT, R

2.97

3.3

3.63

V

Data Rate:

Fibre Channel

Ethernet

1.0625

1.25

Gb/s

1

Note:

1. Recommended operating conditions are those values outside of which functional performance is not intended, device reliability is not implied, and

damage to the device may occur over an extended period of time. See Reliability Data Sheet for specific reliability performance.

Process Compatibility

Parameter

Symbol

Minimum

Typical

Maximum

Unit

Notes

Hand Lead Solder:

Temperature

Time

T_solder

t_time

+260

10

°C

sec

Wave Solder and

Aqueous Wash:

Temperature

Time

T_solder

t_time

+260

10

°C

sec

1

Note:

1. Aqueous wash pressure < 110 psi.

7

Transceiver Electrical Characteristics

(T = -10 °C to +85 °C, V T, R = 3.3 V 10%)

C

CC

Parameter

Symbol

Minimum

Typical

Maximum

Unit

Notes

AC Electrical Characteristics

Power Supply Noise Rejection

(Peak-to-Peak)

PSNR

100

mV

1

DC Electrical Characteristics

Module Supply Current

Power Dissipation

I_CC

200

726

mA

P_DISS

mW

Sense Outputs:

Signal Detect [SD]

V_OH

V_OL

2.4

V_CCR + 0.3

0.4

V

2

3

Control Inputs:

Transmitter Disable

[TX_DISABLE]

V_IH

V_IL

2.4

0.0

V_CC+ 0.3

0.4

V

Notes:

1. MSA filter is required on host board 10 Hz to 2 MHz.

2. LVTTL, 1.2 kW internal pull-up resistor to V R.

CC

3. 9.0 KW internal pull-down resistor to V

EE.

4. Please refer to the HFBR-59L1AL characterization report for typical values.

8

Transmitter and Receiver Electrical Characteristics

(T = -10 °C to +85 °C, V T, R = 3.3 V 10%)

C

CC

Parameter

Symbol

Minimum

Typical

Maximum

Unit

Notes

Data Input:

V_I

400

2400

mV

1

Transmitter Differential Input

Voltage (TD +/-)

Data Output:

Receiver Differential Output

Voltage (RD +/-)

V_O

400

625

2000

200

mV

ps

2

Receive Data Rise and Fall

Times (Receiver)

T_rise/fall

3

Contributed Deterministic Jitter

(Receiver) 1.25 Gb/s

DJ

0.212

170

UI

ps

UI

ps

UI

ps

UI

ps

4, 6

Contributed Deterministic Jitter

(Receiver) 1.0625 Gb/s

DJ

RJ

0.12

113

Contributed Random Jitter

(Receiver) 1.25 Gb/s

0.120

96

5, 6

Contributed Random Jitter

(Receiver) 1.0625 Gb/s

0.098

92

Notes:

1. Internally ac coupled and terminated (100 Ohm differential). These levels are compatible with CML and LVPECL voltage swings.

2. Internally ac coupled with internal 50 Ohm pullups to V (single-ended) and a required external 100 Ohm differential load termination.

CC

3. 20% - 80% rise and fall times measured with a 500 MHz signal utilizing a 1010 data pattern.

4. Contributed DJ is measured on an oscilloscope in average mode with 50% threshold and K28.5 pattern.

5. Contributed RJ is calculated for 1x10-12 BER by multiplying the RMS jitter (measured on a single rise or fall edge) from the oscilloscope by 14. Per

the FC-PI standard (Table 13 - MM jitter output, note 1), the actual contributed RJ is allowed to increase above its limit if the actual contributed DJ

decreases below its limits, as long as the component output DJ and TJ remain within their specified FC-PI maximum limits with the worst case

specified component jitter input.

6. In a network link, each component’s output jitter equals each component’s input jitter combined with each component’s contributed jitter.

Contributed DJ adds in a linear fashion and contributed RJ adds in a RMS fashion. In the Fibre Channel specification, there is a table specifying the

input and output DJ and TJ for the receiver at each data rate. In that table, RJ is found from TJ –DJ, where the Rx input jitter is noted as Gamma R,

and the Rx output jitter is noted as Delta R. The HFBR-59L1AL contributed jitter is such that, if the maximum specified input jitter is present, and is

combined with our maximum contributed jitter, then we meet the specified maximum output jitter limits listed in the FC-PI MM jitter specification

table.

7. Please refer to the HFBR-59L1AL characterization report for typical values.

9

Transmitter Optical Characteristics

(T = -10 °C to +85 °C, V T, R = 3.3 V 10%)

C

CC

Parameter

Symbol

Minimum

Typical

Maximum

Unit

Notes

Output Optical Power (Average)

POUT

-10

0

dBm

50/125 µm

NA = 0.2

Note 1

POUT

-10

0

dBm

62.5/125 µm

NA = 0.275

Note 1

Optical Extinction Ratio

ER

9

dB

Optical Modulation Amplitude

(Peak-to-Peak) 1.0625 Gb/s

OMA

156

µW

FC-PI Std

Note 3

l_C

Center Wavelength

Spectral Width - rms

Optical Rise/Fall Time

830

860

0.85

150

nm

ps

FC-PI Std

s

T_rise/fall

20%-80%,

FC-PI Std

RIN₁₂(OMA), maximum

RIN

DJ

RJ

P_OFF

-117

0.1

dB/Hz

UI

FC-PI Std

Contributed Deterministic Jitter

(Transmitter) 1.25 Gb/s

Notes 3, 4

80

ps

Contributed Deterministic Jitter

(Transmitter) 1.0625 Gb/s

.009

85

UI

Notes 3, 4

Notes 4, 5

ps

Contributed Random Jitter

(Transmitter) 1.25 Gb/s

.184

147

.177

167

-35

UI

ps

Contributed Random Jitter

(Transmitter) 1.0625 Gb/s

UI

ps

P_OUTTX_DISABLE Asserted

dBm

Notes:

1. Max Pout is the lesser of 0 dBm or Maximum allowable per Eye Safety Standard.

2. An OMA of 156 is approximately equal to an average power of –10 dBm assuming an Extinction Ratio of 9 dB.

3. Contributed DJ is measured on an oscilloscope in average mode with 50% threshold and K28.5 pattern.

4. Contributed RJ is calculated for 1x10-12 BER by multiplying the RMS jitter (measured on a single rise or fall edge) from the oscilloscope by 14. Per

the FC-PI standard (Table 13 - MM jitter output, note 1), the actual contributed RJ is allowed to increase above its limit if the actual contributed DJ

decreases below its limits, as long as the component output DJ and TJ remain within their specified FC-PI maximum limits with the worst case

specified component jitter input.

5. In a network link, each component’s output jitter equals each component’s input jitter combined with each component’s contributed jitter.

Contributed DJ adds in a linear fashion and contributed RJ adds in a RMS fashion. In the Fibre Channel specification, there is a table specifying the

input and output DJ and TJ for the transmitter at each data rate. In that table, RJ is found from TJ – DJ, where the TX input jitter is noted as Delta T,

and the TX output jitter is noted as Gamma T. The HFBR-59L1AL contributed jitter is such that, if the maximum specified input jitter is present, and is

combined with our maximum contributed jitter, then we meet the specified maximum output jitter limits listed in the FC-PI MM jitter specification

table.

6. Please refer to the HFBR-59L1AL characterization report for typical values.

10

Receiver Optical Characteristics

(T = -10 °C to +85 °C, V T, R = 3.3 V 10%)

C

CC

Parameter

Optical Power

Symbol

Minimum

Typical

Maximum

Unit

dBm

Notes

FC-PI Std

Note 1

0

Receiver Sensitivity (Optical

Input Power) 1.25 Gb/s

PRMIN

-17

Min Optical Modulation

Amplitude (Peak-to-Peak)

1.0625 Gb/s

OMA

31

µW

FC-PI Std

Note 2

Stressed Receiver Sensitivity

62.5 µm fiber 1.25 Gb/s

62.5 µm fiber 1.0625 Gb/s

PRMIN

OMA

-12.5

-13.5

dBm

µW

Note 3

Note 4

67

50 µm fiber 1.25 Gb/s

50 µm fiber 1.0625 Gb/

PRMIN

OMA

dBm

µW

55

12

Return Loss

dB

FC-PI Std

Note 5

Signal Detect - De-Assert

Signal Detect - Assert

Signal Detect - Hysteresis

P_D

-31

-17.5

-17.0

5

dBm

dB

P_A

Note 5

P_A- P_D

0.5

2.1

Notes:

-12

1. Sensitivity measurements are made at eye center with BER = 1E

.

2. An OMA of 31 is approximately equal to an average power of –17 dBm assuming an Extinction Ratio of 9 dB.

3. 1.25 Gb/s Stressed receiver vertical eye closure penalty (ISI) min is 2.2 dB for 50 µm fiber and 2.6 dB for 62.5 µm fiber. Stressed receiver DCD

component min (at TX) is 65 ps.

4. 1.0625 Gb/s Stressed receiver vertical eye closure penalty (ISI) min is 0.96 dB for 50 µm fiber and 2.18 dB for 62.5 µm fiber. Stressed receiver DCD

component min (at TX) is 80 ps.

5. These average power values are specified with an Extinction Ratio of 9 dB. The Signal Detect circuitry responds to OMA (peak-to-peak) power, not

to average power.

6. Please refer to the HFBR-59L1AL characterization report for typical values.

Transceiver Timing Characteristics

(T = -10 °C to +85 °C, V T, R = 3.3 V 10%)

C

CC

Parameter

Symbol

t_off

Minimum

Typical

Maximum

Unit

µs

Notes

TX Disable Assert Time

TX Disable Negate Time

Time to Initialize

TX Disable to Reset

SD Assert Time

SD De-assert Time

10

1

2

3

4

5

6

t_on

ms

µs

t_init

300

t_reset

t_loss_on

t_loss_off

10

100

µs

Notes:

1. Time from rising edge of TX Disable to when the optical output falls below 10% of nominal.

2. Time from falling edge of TX Disable to when the modulated optical output rises above 90% of nominal.

3. From power on or negation of TX Fault using TX Disable.

4. Time TX Disable must be held high to reset TX Fault.

5. Time from optical signal loss to SD assert. See transceiver timing diagrams.

6. Time from optical signal recovery to SD deassert. See transceiver timing diagrams.

11

V

CC

> 2.97 V

V

CC

> 2.97 V

Tx_FAULT

Tx_DISABLE

TRANSMITTED SIGNAL

t_init

t-init: TX DISABLE DE-ASSERTED

t-init: TX DISABLE ASSERTED

Tx_FAULT

Tx_DISABLE

TRANSMITTED SIGNAL

t_off

t_on

t-off & t-on: TX DISABLE ASSERTED THEN NEGATED

OCCURANCE OF FAULT

Tx_FAULT

Tx_DISABLE

TRANSMITTED SIGNAL

t_reset

* SFP SHALL CLEAR TX_FAULT IN

t_init*

< t_init IF THE FAILURE IS TRANSIENT

t-reset: TX DISABLE ASSERTED THEN NEGATED, TX SIGNAL RECOVERED

OCCURANCE

OF LOSS

OPTICAL SIGNAL

Rx_SD

t_loss_on

t_loss_off

t-loss-on & t-loss-off

Figure 5. Transceiver timing diagrams.

12

AGILENT HFBR-59L1AL

850 nm LASER PROD

21CFR(J) CLASS 1

COUNTRY OF ORIGIN YYWW

XXXXXX

15.05

(0.593)

13.59

(0.535)

MAX.

UNCOMPRESSED

THERMOCOUPLE

TEST POINT

48.19

(1.897)

6.25 0.05

(0.246 0.002)

13.63

(0.537)

9.80

(0.39)

MAX.

TX

RX

3.25

(0.128)

10.80

(0.425)

UNCOMPRESSED

14.68

(0.578)

1.00

4 x

10.16

(0.400)

(0.039)

2.92

(0.115)

MIN.

10.16

(0.400)

4.57

(0.180)

13.34

(0.525)

7.11

(0.280)

28.45

(1.120)

0

1.07

–0.10

2 x ∅

+0.000

17.79

(0.700)

(0.042

)

–0.004

AREA

FOR

6 7 8 9 10

13.00 0.10

(0.512 0.004)

PROCESS

PLUG

5 4 3 2

1

14.20 0.10

(0.559 0.004)

19.59

(0.771)

0.46 0.05

10 x

∅

(0.018 0.002)

DIMENSIONS ARE IN MILLIMETERS (INCHES)

Figure 6a. Module drawing.

13

∅0.00 M A

0.81 0.10

20x ∅

(0.032 0.004)

25.75

(1.014)

SEE NOTE 3

∅0.00 M A

1.40 0.10

4x ∅

(NOTE 5)

(0.055 0.004)

SEE DET AIL A

13.34

(0.525)

12.16

(0.479)

15.24

(0.600)

MINIMUM PITCH

5432

1

7.59

10.16

(0.299) (0.400)

678910

4.57 (0.180)

SEE DETAIL B

7.11 (0.280)

8.89 (0.350)

3.56

(0.140)

1.78

9x

(0.070)

2.29

(0.090)

2x ∅

MAX.(AREA FOR EYELETS)

1.40 0.10

2x ∅

(NOTE 4)

(0.055 0.004)

3.00

(0.118)

1.80

(0.071)

∅0.00 M A

3.00

(0.118)

6.00

(0.236)

1.00

(0.039)

DETAIL A (3x)

DETAIL B (4x)

15.24

MIN.PITCH

(0.600)

14.22 0.10

(0.560 0.004)

+1.50

–0

1.00

A

+0.059

(0.039

)

–0.000

A

10.16 0.10

(0.400 0.004)

TOP OF PCB

12

REF. MAX.

(0.472)

A

+0

SECTION A-A

15.75

–0.75

+0.000

(0.620

)

–0.030

Notes:

1. This page describes the recommended circuit board layout and front panel openings for SFF transceivers.

2. The hatched areas are keep-out areas reserved for housing standoffs. No metal traces allowed in keep-out areas..

3. The drawing shows extra pin holes for 2x10 pin transceivers. These extra holes are not required for HFBR-59L1AL.

4. Holes for mounting studs must be tied to chassis ground.

5. Holes for housing leads mst be tied to signal ground.

6. Dimensions are in millimeters (inches).

Figure 6b. Recommended SFF host board and front panel layout.

14

www.agilent.com/

semiconductors

For product information and a complete list of

distributors, please go to our web site.

For technical assistance call:

Americas/Canada: +1 (800) 235-0312 or

(408)654-8675

Europe: +49 (0) 6441 92460

China: 10800 650 0017

Hong Kong: (+65) 6271 2451

India, Australia, New Zealand: (+65) 6271 2394

Japan: (+81 3) 3335-8152(Domestic/International), or

0120-61-1280(DomesticOnly)

Korea: (+65) 6271 2194

Malaysia, Singapore: (+65) 6271 2054

Taiwan: (+65) 6271 2654

Data subject to change.

March 3, 2003

5988-7944EN


型号：	HFBR-59L1AL
厂家：	HEWLETT-PACKARD
描述：	Agilent HFBR-59L1AL 1.25 GBd Ethernet and 1.0625 GBd Fibre Channel 850 nm SFF Low Voltage (3.3 V) Optical Transceiver 安捷伦HFBR- 59L1AL 1.25 GBd的以太网和1.0625 GBd的光纤通道850 nm的SFF低电压（ 3.3 V ）光收发器光纤放大器以太网通信
文件：	总15页 (文件大小：310K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

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