HFBR-0527P Avago Technologies US Inc., HFBR-0527P Datasheet - Page 7

HFBR-0527P

Manufacturer Part Number

HFBR-0527P

Description

Fiber Optics, Evaluation Kit

Manufacturer

Avago Technologies US Inc.

Datasheets

1.HFBR-0527H.pdf (16 pages)

2.HFBR-0527P.pdf (1 pages)

Specifications of HFBR-0527P

Kit Contents

TX/RX Mods, Cable, Pol Kit, SW, Pwr. Sup

Tool / Board Applications

Fiber Optic Transceivers

Mcu Supported Families

HFBR-1527, HFBR-2526

Main Purpose

Interface, Fiber Optics

Embedded

Utilized Ic / Part

HFBR-1527, HFBR-2526

Primary Attributes

125MBd, Communication up to 25m

Secondary Attributes

650nm LED, 1mm POF

Description/function

Fiber Optic Kit

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

For Use With/related Products

HFBR-1527, HFBR-2526

Lead Free Status / RoHS Status

Lead free / RoHS Compliant, Lead free / RoHS Compliant

Other names

516-2143
HFBR-0527P

Current page: 7 of 16
Download datasheet (362Kb)

The transmitters shown in Figures 5 and 6 use the following

techniques to improve LED performance. When the output

of U1 is a logic “1”, resistor R11 applies a small residual prebias

current to the LED. This small prebias current minimizes

the propagation delay distortion of the LED. Prebias also

improves LED linearity sufficiently to permit the use of a

frequency compensation circuit, which reduces the optical

rise/fall time of the fiber optic transmitter.

This frequency compensation technique is often called

drive current peaking, because it adds brief current spikes

to the LED drive current pulses.When prebiased, the HFBR-

15X7Z LED has an amplitude versus frequency response

which is roughly equivalent to a first order low-pass filter.

Without prebias and peaking, the HFBR-15X7Z LED has a

typical 10% to 90% optical rise time of 12 ns. When prebias

is provided by R11, and frequency compensation (peaking)

is provided by R10, and C8, the 10% to 90% optical rise time

of the HFBR-15X7Z LED decreases to a typical value of 3 ns,

when using 1 mm plastic fiber. Optical rise times of 3.5 ns

are typical when the peaked LED driver is used with 200

µm HCS fiber. The LED’s on-state current is primarily deter-

mined by the values of resistors R8 and R9, but Equation 1

shows that some on-state current is also provided by R11.

Transistor Q3 is connected to form a low cost high speed

diode. This diode allows LED prebias current to be set inde-

pendent of the resistance chosen for R8 and R9. The LED’s

prebias current can be calculated as shown in Equation 2.

Capacitance between the emitter and collector of Q3

changes as a function of the diode connected transistor’s

forward current. Current dependent changes in the capaci-

tance of Q3 ensure that the current peak which turns the

LED off will have a larger amplitude than the current peak

applied when the LED is switched on. LEDs are character-

istically harder to turn off than on. The difference between

the amplitude of the peak current applied at turn on, and

turn off, helps to reduce the optical pulse width distortion

of the fiber optic transmitter. One of the best features of this

recommended LED driver circuit is that all of the active and

passive components needed to build 10,000 of the trans-

mitters shown in Figures 5 or 6 can be purchased for about

$8.00 per circuit.

Recommended Receiver

The recommended receiver is shown in Figure 7. The HFBR-

25X6Z component used in this receiver linearly converts

changes in received optical power to a corresponding

change in voltage. The output of the HFBR-25X6Z is an

analog signal which can easily be converted to logic by a

post amplifier and comparator. This post amplifier com-

parator function is often called a quantizer. A very inexpen-

sive quantizer can be implemented using an MC10H116

ECL line receiver. The MC10H116 provides three low cost

differential amplifiers in a single package. The MC10H116

can accommodate a large range of input voltages. The

large dynamic range of the MC10H116 is very important! The

quantizer must have a large dynamic range because the

output of the HFBR-25X6Z can change from a few millivolts

to hundreds of millivolts when fiber length and attenuation

are varied.

Several subtle techniques are used to maximize the re-

ceiver’s sensitivity to optical pulses, while minimizing the

receiver susceptibility to electromagnetic interference (EMI).

In most systems, the same +5 V DC supply which powers

the fiber optic receiver is also used to power microproces-

sors and digital logic. The receiver must be isolated from noisy

dc power supplies! This isolation is provided by low-pass

filters that prevent noise injection into the HFBR-25X6Z, and

quantizer, through the +5 V power connections. The HFBR-

25X6Z is a miniature hybrid circuit that, due to its small

physical size, is relatively immune to environmental noise.

In most applications, the HFBR-25X6Z has sufficient noise

immunity to operate without any additional electrostatic

shielding, but the connection between the HFBR-25X6Z

and the non-inverting input of the MC10H116 forms a loop

antenna with sufficient area to receive significant amounts

of EMI. The receiver’s susceptibility to EMI is minimized by

connecting a second loop antenna with equal area to the

inverting input of the MC10H116 quantizer. When connec-

tions to the quantizer’s input are symmetric, and have equal

loop areas, the common mode rejection of the MC10H116’s

difference amplifiers will assure that the fiber optic receiver

provides good EMI immunity.

Design techniques which improve the EMI immunity of the

receiver help to minimize crosstalk between the transmitter

and the receiver. Crosstalk will also be reduced when the

printed circuit for the fiber optic transceiver is designed so

that pin 4 of the HFBR-15X7Z LED transmitter is next to pin

1 of the HFBR-25X6Z receiver. This arrangement maximizes

the distance between pin 2 of the HFBR-15X7Z LED and the

power supply lead (pin 4) of the HFBR-25X6Z. When the

distance between pin 4 of the HFBR-25X6Z and pin 2 of

the LED is maximized, the crosstalk between the LED trans-

mitter and the HFBR-25X6Z receiver’s power pin is reduced.

The typical transmitter to receiver crosstalk which occurs

when using the printed circuit shown in this application

note is equivalent to a 0.5 dB reduction in receiver sensi-

tivity. The effect of transceiver crosstalk has already been

factored into the recommended distances and data rates

shown in Figures 1 and 2.

Equation 1:

Equation 2:

Equations

F ON

F OFF

(V cc - V

R11

F ON

F OFF

)

[V cc - (V

[(R8)(R9)/(R8 + R9)]

F ON

+ V

CE Q3

+ V

OL U1

)]

HFBR-0527P Avago Technologies US Inc., HFBR-0527P Datasheet - Page 7

HFBR-0527P

Specifications of HFBR-0527P

Related parts for HFBR-0527P