English
Language : 

MIC3001 Datasheet, PDF (20/74 Pages) Micrel Semiconductor – SFP Management IC with Internal Calibration
MIC3001
RXPOT
A programmable, non-volatile digitally controlled potentiom-
eter is provided for adjusting the gain of the receive power
measurement signal chain in the analog domain. Five bits in
the RXPOT register are used to set and adjust the position of
potentiometer. RXPOT functions as a programmable divider
or attenuator. It is adjustable in steps from 1:1 (no divider
action) down to 1/32 in steps of 1/32. If RXPOT is set to zero,
the divider is bypassed completely. There will be no scaling
of the input signal, and the resistor network will be discon-
nected from the VRX pin. At all other settings of RXPOT, there
will be a 32kΩ (typical) load seen on VRX.
VRX
ADC
R1
R2
R3
32:1
MUX
R30
R31
R32
RXPOT[4:0] 5
Figure 3. RXPOT Block Diagram
Laser Diode Bias Control
The MIC3001 can be configured to generate a constant bias
current using electrical feedback, or regulate average trans-
mitted optical power using a feedback signal from a monitor
photodiode, see Figure 4. An operational amplifier is used to
control laser bias current via the VBIAS output. The VBIAS pin
can drive a maximum of ±10mA. An external bipolar transistor
provides current gain. The polarity of the op amp’s output is
programmable BIASREF in OEMCFG1 in order to accommo-
date either NPN or PNP transistors that drive common anode
and common cathode laser, respectively. Additionally, the
polarity of the feedback signal is programmable for use with
either common-emitter or emitter-follower transistor circuits.
Furthermore, the reference level for the APC circuit is select-
able to accommodate electrical, i.e., current feedback, or
optical feedback via a monitor photodiode. Finally, any one of
seven different internal feedback resistors can be selected.
This internal resistor can be used alone or in parallel with an
external resistor. This wide range of adjustability (50:1)
accommodates a wide range of photodiode current, i.e, wide
range of transmitter output power. The APC operating point
can be kept near the mid-scale value of the APC DAC,
insuring maximum SNR, maximum effective resolution for
digital diagnostics, and the widest possible DAC adjustment
range for temperature compensation, etc. See Figure 5.
Micrel
The APCCAL bit in OEMCAL0 is used to turn the APC
function on and off. It will be turned off in the MIC3001’s
default state as shipped from the factory. When APC is on,
the value in the selected APCSETx register is added to the
signed value taken from the APC look-up table and loaded
into the VBIAS DAC. When APC is off, the VBIAS DAC may be
written directly via the VBIAS register, bypassing the look-up
table entirely. This provides direct control of the laser diode
bias during setup and calibration. In either case, the VBIAS
DAC setting is reported in the APCDAC register. The APCCFG
bits determine the DACs response to higher or lower numeric
values.
VOUT
DAC
VDD-OUT
GAIN
APC
Look-Up
INV
Table
APCSET
Temp
Sensor
RFB[2:0]
VDD
BIASREF
VMOD
Look-Up
Table
MODSET
DAC
VOUT
VDD-OUT
MODREF
VBIAS
COMP
FB
VMOD
VMOD–
Figure 4. MIC3001 APC and Modulation Control
Block Diagram
APC Op-Amp
FB
R7 R6 R5 R4 R3 R2 R1
51.2k 25.6k 12.8k 6.4k 3.2k 1.6k 0.8k
VDD
RFB[2:0] 7
BIASREF
Figure 5. Programmable Feedback Resistor
Laser Modulation Control
As shown in Figure 4, a temperature-compensated DAC is
provided to set and control the laser modulation current via an
external laser driver circuit. MODREF in OEMCFG0 selects
whether the VMOD DAC output swings up from ground or
down from VDD. If the laser driver requires a voltage input to
set the modulation current, the MIC3001’s VMOD output can
drive it directly. If a current input is required, a fixed resistor
can be used between the driver and the VMOD output. Several
different configurations are possible as shown in Figure 7.
M9999-082404
20
August 2004