MAX3664 Maxim, MAX3664 Datasheet - Page 5

MAX3664

Manufacturer Part Number

MAX3664

Description

622Mbps / Ultra-Low-Power / 3.3V Transimpedance Preamplifier for SDH/SONET

Manufacturer

Maxim

Datasheets

1.MAX3664.pdf (12 pages)

2.MAX3664.pdf (12 pages)

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________________Detailed Description

The MAX3664 is a transimpedance amplifier designed

for 622Mbps SDH/SONET applications. It comprises a

transimpedance amplifier, a paraphase amplifier with

emitter-follower outputs, and a DC cancellation loop.

Figure 1 is a functional diagram of the MAX3664.

The signal current at IN flows into the summing node of

a high-gain amplifier. Shunt feedback through R

verts this current to a voltage with a gain of 6kΩ. Diode

D1 clamps the output voltage for large input currents.

INREF1 is a direct connection to the emitter of the input

transistor, and must be connected directly to the pho-

todetector AC ground return for best performance.

The paraphase amplifier converts single-ended inputs to

differential outputs, and introduces a voltage gain of 2.

This signal drives a pair of internally biased emitter follow-

ers, Q2 and Q3, which form the output stage. Resistors

R1 and R2 provide back-termination at the output,

absorbing reflections between the MAX3664 and its load.

The output emitter followers are designed to drive a

100Ω differential load between OUT+ and OUT-. They

can also drive higher output impedances, resulting in

increased gain and output voltage swing.

The DC cancellation loop removes the DC component

of the input signal by using low-frequency feedback.

This feature centers the signal within the MAX3664’s

dynamic range, reducing pulse-width distortion on

large input signals.

The output of the paraphase amplifier is sensed through

resistors R3 and R4 and then filtered, amplified, and fed

back to the base of transistor Q4. The transistor draws

the DC component of the input signal away from the

transimpedance amplifier’s summing node.

The COMP pin sets the DC cancellation loop’s

response. Connect 400pF or more between COMP and

GND for normal operation. Connect the pin directly to

GND to disable the loop. The DC cancellation loop can

sink up to 300µA of current at the input. When operated

with C

20µs to stabilize.

The MAX3664 minimizes pulse-width distortion for data

sequences that exhibit a 50% duty cycle. A duty cycle

other than 50% causes the device to generate pulse-

width distortion.

DC cancellation current is drawn from the input and

adds noise. For low-level signals with little or no DC

Transimpedance Preamplifier for SDH/SONET

COMP

= 400pF, the loop takes approximately

_______________________________________________________________________________________

Transimpedance Amplifier

DC Cancellation Loop

Paraphase Amplifier

622Mbps, Ultra-Low-Power, 3.3V

con-

component, this is not a problem. Preamplifier noise will

increase for signals with significant DC component.

___________Applications Information

The MAX3664 is a low-noise, wide-bandwidth transim-

pedance amplifier that is ideal for 622Mbps SDH/

SONET receivers. Its features allow easy design into a

fiber optic module, in four simple steps.

Step 1: Selecting a Preamplifier for a 622Mbps

Receiver

Fiber optic systems place requirements on the band-

width, gain, and noise of the transimpedance preampli-

fier. The MAX3664 optimizes these characteristics for

SDH/SONET receiver applications that operate at

622Mbps.

In general, the bandwidth of a fiber optic preamplifier

should be 0.6 to 1 times the data rate. Therefore, in a

622Mbps system, the bandwidth should be between

375MHz and 622MHz. Lower bandwidth causes pat-

tern-dependent jitter and a lower signal-to-noise ratio,

while higher bandwidth increases thermal noise. The

MAX3664 typical bandwidth is 590MHz, making it ideal

for 622Mbps applications.

The preamplifier’s transimpedance must be high

enough to ensure that expected input signals generate

output levels exceeding the sensitivity of the limiting

amplifier (quantizer) in the following stage. The

MAX3675 clock recovery and limiting amplifier IC has

an input sensitivity of 3.6mVp-p, which means that

3.6mVp-p is the minimum signal amplitude required to

produce a fully limited output. Therefore, when used

with the MAX3664, which has a 6kΩ transimpedance,

the minimum detectable photodetector current is 600nA.

It is common to relate peak-to-peak input signals to

average optical power. The relationship between opti-

cal input power and output current for a photodetector

is called the responsivity ( ), with units Amperes/Watt

(A/W). The photodetector peak-to-peak current is relat-

ed to the peak-to-peak optical power as follows:

Based on the assumption that SDH/SONET signals

maintain a 50% duty cycle, the following equations

relate peak-to-peak optical power to average optical

power and extinction ratio (Figure 2):

Therefore,

Average Optical Power = P

Extinction Ratio = r

Peak-to-Peak Signal Amplitude = Pp-p = P1 - P0

AVE

= Pp-p (1 / 2)[(r

Ip-p = (Pp-p)( )

= P1 / P0

AVE

+ 1) / (r

= (P0 + P1) / 2

- 1)]

MAX3664 Maxim, MAX3664 Datasheet - Page 5

MAX3664

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