MAX3864(2000) Ver la hoja de datos (PDF) - Maxim Integrated
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MAX3864
(Rev.:2000)
(Rev.:2000)
Maxim Integrated
MAX3864 Datasheet PDF : 12 Pages
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2.5Gbps, +3V to +5.5V, Wide Dynamic Range
Transimpedance Preamplifier
POWER
PI
PAVG
PIN
PO
TIME
Figure 4. Optical Power Relations
Table 1. Optical Power Relations
PARAMETER SYMBOL
RELATION
Average Power
PAVE
PAVE = (P0 + P1) / 2
Extinction Ratio
re
re = P1 / P0
Optical Power of a 1
P1
P1 = 2PAVEre / (re + 1)
Optical Power of a 0
P0
P0 = 2PAVE / (re + 1)
Signal Amplitude
PIN
PIN = P1 - P0 = 2PAVE
(re - 1) / (re + 1)
Note: Assuming a 50% average input duty cycle and mark
density.
Applications Information
Optical Power Relations
Many of the MAX3864 specifications relate to the input
signal amplitude. When working with fiber optic receivers,
the input is usually expressed in terms of average optical
power and extinction ratio. Figure 4 shows relations that
are helpful for converting optical power to input signal
when designing with the MAX3864.
Optical power relations are shown in Table 1; the defini-
tions are true if the average duty cycle and mark densi-
ty of the input data are 50%.
Optical Sensitivity Calculations
The MAX3864 input-referred RMS noise current (IN)
generally determines the receiver sensitivity. To obtain
a system bit-error rate (BER) of 1E-10, the minimum sig-
nal-to-noise ratio (SNR) is 12.7. The input sensitivity,
expressed in average power, can be estimated as:
Sensitivity =10log
SNR × IN(re + 1)
2ρ(re
−1)
×
1000
dBm
where ρ is the photodiode responsivity, including fiber-
to-photodiode coupling efficiency in A/W and IN in µA.
For example, if SNR = 12.7, IN = 0.490µA, re = 10, and
ρ = 1, then sensitivity is -24dBm.
Input Optical Overload
The overload is the largest input that the MAX3864
accepts while meeting deterministic jitter specifications.
The optical overload can be estimated in terms of aver-
age power with the following equation (assumes
re = ∞):
Overload
=
10log
2mAp - p ×
2ρ
1000
dBm
Optical Linear Range
The MAX3864 has high gain, which limits the outputs
when the input signal exceeds 40µAp-p. The MAX3864
operates in a linear range for inputs not exceeding:
Linear
Range
=
10log
40µAp -p(re + 1)
2ρ(re −1)
×
1000
dBm
Layout Considerations
Use good high-frequency design and layout techniques.
The use of a multilayer circuit board with separate ground
and power planes is recommended. Connect the GND
pins to the ground plane with the shortest possible traces.
Noise performance and bandwidth will be adversely
affected by capacitance at the IN pin. Minimize capaci-
tance on this pin, and select a low-capacitance photodi-
ode. Assembling the MAX3864 in die form using chip and
wire technology provides the best possible performance.
Figure 5 shows the recommended layout for a TO
header.
The SO package version of the MAX3864 is offered as an
easy way to characterize the circuit and to become famil-
iar with the circuit’s operation, but it does not offer opti-
mum performance. When using the SO version of the
MAX3864, the package capacitance adds approximately
0.3pF at the input. The PC board between the MAX3864
input and the photodiode also adds parasitic capaci-
tance. Keep the input line short, and remove power and
ground planes beneath it.
GND
Connect GND as close to the AC ground of the photode-
tector diode as possible. The photodetector AC ground is
usually the ground of the filter capacitor from the photode-
tector cathode. The total loop (from GND, through the
bypass capacitor and the diode, and back to IN) should
be no more than approximately 1/5th of a wavelength.
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